Daniel and Kelly’s Extraordinary Universe - Phage therapy (featuring Dr. Katrine Whiteson)
Episode Date: August 28, 2025Daniel and Kelly chat with Katrine Whiteson about how we can enlist viruses to kill infectious bacteria.See omnystudio.com/listener for privacy information....
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There's a battle being fought every minute of every day.
It isn't a traditional war on the battlefield between armies of soldiers.
It's a battle within us between our immune system and invading microbes.
And we're not alone fighting off pathogens.
We have hosts of microbial allies.
Inside our bodies are multitudes of microbes,
some helping us digest others starving out potential invaders.
But until recently, infections were too often deadly,
and there was not much we could do other than try to avoid them.
Treatment options were thin.
But almost 100 years ago, we discovered a powerful new ally.
Some fungi were the enemy of our enemy, able to kill bacteria and halt infections.
And so antibiotics became our friends.
But bacteria respond and evolved, developing protections against antibiotics and overcoming them.
It's possible again today to become infected by a resistant strain and for doctors to have no real treatment options.
Is it time to recruit a new ally?
in the microbial war?
Today we'll welcome a visiting dignitary
and expert working on the front lines
to find microbes capable of killing resistant bacteria
with techniques that can be tailored
to produce the particular microbe
needed to halt your individual infection.
Welcome to Daniel and Kelly's
extraordinarily individual universe.
Hello, this is Kelly Weiner-Smith.
I study parasites and space.
And I think probably maybe the second or third critter on our planet was probably a parasite taking advantage of the first.
Hi, I'm Daniel.
I'm a particle physicist and professor at UC Irvine.
And I'm definitely the second most useful person at the Whiteson Institute for Advanced Science.
And the good news is today we're getting the first most useful person.
back on the show. This is the third time Katrina has joined you and I, and I enjoy it every single
time. Yeah, listeners seem to really enjoy having her on. And, of course, I love talking to
Katrina. And she knows so much about so many fascinating topics, especially the topic we're
tackling today. Yeah, and today we learned a really fascinating fact about what kind of
organism on our planet is the most common. And I was, I can maybe a little bit surprised.
But so, Daniel, I'll give you a little quiz here. You were hoping she was going to say parasites,
wouldn't you?
Well, I mean, the answer is a kind of parasite, really, or pathogen, depending on how you define
these things.
So I felt very validated today during our conversation.
But Daniel, if you had to guess what order of animals, and remember, it's kingdom phylum class
order, what order of animals has the most species in it?
This is totally fair because I do a pop quiz on our listeners all the time.
And so here I've had no chance to prepare.
Your turn.
I'm going to have to go beetles.
Is it beetles or ants?
You have perhaps heard that folks think beetles are the most common organism out there.
And there's, you know, claims that God loved beetles more than any other organism.
And that's why there were so many beetles on the planet.
But it looks like actually the most common kind of animal is not a beetle, but it's like wasps and hymenopterins.
Because each of those beetle species is infected by one or more wasp,
that lays its eggs inside of those beetles.
And so, yes, you have a lot of hosts,
but you, as is so often the case, and we'll hear more about today,
hosts usually harbor a diverse community of things
that are willing to live inside of them
and eat their insides up.
And there's often more of those than there are the hosts.
Good luck sleeping tonight, friends.
And those parasites have their own bacteria,
and those bacterias have their own little critters that live inside them.
And today, we're going to be hearing about how that all works
and how it might chart a new course
for treatment for difficult infections in humans.
It reminds me of a poem that goes,
Great fleas have little fleas upon their backs to bite them.
And little fleas have lesser fleas, and so ad infinitum.
And the great fleas themselves in turn have greater fleas to go on,
while these, again, have greater still and greater still, and so on.
Anyway, so there's always levels of infection going on.
It's infection all the way down.
It's amazing.
Sure is.
And so on today's program, we have my wonderful wife and colleague at the Whiteson Institute,
who is coming back to the podcast to tell us about how she personally is developing treatments against resistant bacteria.
Best Whiteson.
Just kidding.
Just kidding.
Totally 100% agree with you on that one.
So then it's my pleasure to welcome to the podcast, Katrina Whiteson.
She's a full professor recently promoted from associate professor, congratulations, and Chancellor's Fellow.
at UC Irvine, where she studies microbial communities and how they interact with their hosts.
That's us, we're the hosts.
She also holds a dual appointment at the Whiteson Institute for Advanced Science,
where she's the director for wet lab science, not just stuff on the computer,
and has won awards for her innovative salad dressing recipes
and her energetic insertion of chia seeds into every possible recipe.
Katrina, welcome back to the podcast.
Thank you very much for the overly kind introduction.
Well, if this whole podcast and science thing doesn't work out, I'm counting on you to launch
a line of salad dressings featuring chia seeds.
Okay.
I could probably do that.
I just hope this time people would like to have a second helping.
That's all.
Is this an inside joke?
Does Daniel not have second helpings of salad or something?
No, no.
Katrina was one time making salad, and we didn't have any vinegar, so she drained a jar of pickles
and used pickle juice in the salad dressing.
And one of our guests called it a.
one helping kind of salad dressing.
Only after they learned what I had put in there,
they were gobbling it up just fine before I said anything.
Oh, I see.
I see.
We should never tell people what's in the food until the end of the meal.
Very end.
But I imagine you could make a salad dressing with all kinds of like microbiome-related claims.
I would probably buy it.
It's true.
But today we're not here to talk about how to make your salad tasty.
We're here to understand how to stay healthy and what's going on inside all
of us. And so we want to get to the topic of phage therapy, but let's set the stage and remind
ourselves what's going on with traditional antibiotics. So like give us the very basics. When you take
penicillin or you take amoxicillin, what's going on? How do those work? How do those help you
combat pathogens? Well, that's a really big question because each antibiotic is a molecule that has its
own type of mechanism. And so we now have dozens of different kinds of antibiotics. They each work in
different ways. Some of them are called bacteriostatic, so they'll halt the growth of the bacteria.
They won't directly kill them. And others are called bacteriocidal because they can actually kill
the bacteria. But the point is that whichever antibiotic you're taking, the goal is that it's going
to prevent the bacteria from continuing to grow and cause infection. And between the antibiotic
and your immune system, hopefully you're going to end up clearing the infection within a day or
to, you know, all of us have probably had the experience of taking an antibiotic and feeling better
relatively quickly. And that's because the antibiotic is getting in there, stopping or killing
the bacteria, and then your immune system helps clear the infection. And so we've also heard
stories about how before around the era of World War II, when antibiotics became more widely
available, people would often succumb to very normal infections that people survive all the time
right now. So we've become accustomed to being able to survive infections that took people down
before the era of antibiotics and around the time of World War II. I like that. I like that a lot.
For bacteriostatic stuff, is the goal here just that you are trying to make sure they don't grow
any more to give your immune system time to kill them? Or are you making it so they can't
reproduce and the goal is that they'll die of old age at some point? I think either of
those would be good outcomes. So yeah. Okay. But the point is just the population of bacteria is
halted in its tracks, and then your immune system has a better chance to catch up. Got it.
And last time you were on the pod, you were telling us about all the beneficial microbes that live
within us and among us. When you take one of these things, are they somehow targeted towards
pathogens or the things that are hurting you? Or is it just like a nuclear bomb and it's just killing all
of your microbes. That's also nuanced because it depends on the antibiotic, but on average,
antibiotics have broader spectrum, which means that they take out lots of different types of
bacteria, or at least a subset of bacteria. And to be honest, I'm not a deep expert on exactly
what each antibiotic can cover, but it's definitely the case that when you take antibiotics,
you're likely to kill bacteria that we're not causing any trouble at all. So there's pros and
to that. On the pro side, you don't have to think too hard about which antibiotic to take. The doctor can be like, well, your infection is probably kind of one of these types of things, and then this antibiotic will probably take care of the problem. So it's good in that sense. And to be honest, at the time when we started using antibiotics in the mid-20th century, we didn't really appreciate our microbiomes. We thought it'd be great if we could just all be sterile. So it was kind of viewed as a positive, like, yeah, just get rid of all that stuff. That's only causing trouble. And now we actually have
more nuanced appreciation for the fact that we don't want to be decimating our microbes all the
time. So now it's, we kind of appreciate that you don't necessarily want these broader
spectrum antibiotics taking everything out. And some are a little bit more targeted than others.
Totally okay if this question is too far afield and you want to shoot it down. But could we give
an example of how one kind of antibiotic focuses in on one kind of bacteria or a group of
closely related bacteria? I think that's pretty interesting. I guess I had mostly
thought that when you take an antibiotic, you're probably wiping out just about everything.
How do you get certain kinds of bacteria targeted?
Some molecules are focused on certain subsets of bacteria. I mean, for example,
Tobromycin is a recently developed antibiotic that people with cystic fibrosis use to treat
pseudomonas infections in their lungs. And so that has relatively targeted action.
But of course, it can still, my understanding is that it can still kill other,
gram-negative bacteria. There's a few big categories of bacteria and some antibiotics target
broadly those categories. So if you have a gram-negative targeting antibiotic, then your gram-positives
will be protected, for example. And I know there's certain antibiotics that are used when you're
trying to target the anaerobes, which have different metabolisms. So myrapenum, for example,
is something I hear doctors saying they're using to include coverage of the anaerobes. And, you know,
For example, they've even shown that if you take antibiotics that do not target the anaerobes, that can
protect you in the hospital because the anaerobes are the gut bugs that are producing all those
healthy molecules when they digest your fiber. So sparing them by using antibiotics that do not
target anaerobes can be protective. And then I think we did talk about this last time, but if you
decimate all your gut microbes with antibiotics, which happens pretty frequently in the hospital,
then you can be susceptible to other infections like the Clostridia difficile that causes recurrent diarrhea.
All right.
So for hundreds of thousands of years, if you got an infection, you scratched your leg or whatever, you were at risk of dying.
And then for 50 golden years or so, we've had these powerful antibiotics to protect ourselves and to make parents more relaxed when kids are climbing on rusty playground equipment.
but what's happening now?
Why are we hearing so much about antibiotic resistance?
Why are these things not working anymore?
Great question.
Well, to be honest, every time we've started using an antibiotic,
within five or ten years,
we've found bacteria that resist that antibiotic.
So this is not a new problem.
This has been going on ever since we first started using antibiotics.
So during the whole second half of the 20th century,
we got penicillin, and within a couple years,
we had, you know, bugs that could resist the antibiotic penicillin.
But then we would come up with new antibiotics.
And so during the second half of the 20th century, if you look at the timeline of the discovery of antibiotics,
you see all this beautiful new stuff emerging from the pipeline of research every few years.
So there were always new options emerging.
There's a few reasons we don't really have that pipeline right now.
One of them is just the financial structure of the way drugs are being paid.
for in our society because antibiotics typically are acute treatments. And so it's not a lucrative
business for pharmaceutical companies to invest in the production of new antibiotics because, first
of all, if we get a new antibiotic, the doctors are going to conserve it because they don't want
new resistances to emerge. They're going to be like, oh, man, this is my lucky ticket. I'm saving
this for the moment. I really, really need it. But that's going to be completely the opposite of the
profit structure you would need for a pharmaceutical company to be willing to invest. So,
to be honest, it's a little bit of a financial reason, but we've had a real slowdown in the
pipeline of the discovery of antibiotics. There could be something to the fact that we found the low-hanging
fruit, but the truth is the world of microbiology has so much diversity. It's hard to even begin
to explain how little of it we have discovered. Like, we haven't even started to look at 99% of
what's out there. So it's very impossible to me to imagine that we don't have lots of options out there
if we were to put energy into it. We just haven't really had the resources to put energy into it lately.
And so there's been really cool ideas for alternative financial structures that could help.
Like, for example, there was a big meeting at the UN a couple years ago where they were talking about having a
subscription model where countries or pharmaceutical companies or even healthcare companies could pay into a
system where they could have access to a certain drug with a solid rate. And then it didn't matter how much
they actually used it so that there would be a financial structure independent of the use of the
drug. But, I mean, in comparison to the blockbusters like statins or ozempic, you know, antibiotics
are just never going to be as lucrative. So that's a real problem. And then I guess another
thing I absolutely have to say is that about 80% of the antibiotics used, at least in the United
States, are in the context of agriculture. So while we do need to reduce the human use of
antibiotics, and I obviously support antibiotic stewardship programs. The main way that we use
antibiotics and probably where a lot of the resistances are arising is in agriculture. So that's where
we could make a lot of gains if we could reduce the use of antibiotics and animals, which is a hard
thing to do. There's really cool models, like in Denmark, they had to disrupt the relationships
between farmers and veterinarians in order to stop the prescription of antibiotics, because if the
farmer was working with their old buddy veterinarian and asking for a prescription, they would say
yes. It was so hard to get out of the social pressure of doing something you are accustomed to.
But is this because like cows are getting scratches and any treatment, or is it just like
they're pumping antibiotics in because it makes them grow faster? Yes, exactly. Most of the
antibiotics being used in animal agriculture, it's because the antibiotics help the animals grow
faster, which in itself is actually a fascinating science question. Like, why does it make them grow
faster. Maybe it takes some of the energy away from fighting infection, and then you can, like,
put that energy into beefing yourself up. Or literally. Or porking out a little bit, yeah.
I was reading about tuberculosis the other day, and, you know, I think I said in a prior
episode, like, oh, there's all these diseases we don't have to worry about anymore, like tuberculosis.
And then I started reading about tuberculosis, and it's a huge problem in India. And there is recently
a new antibiotic that for these same reasons you mentioned, they've been holding back because
they want to make sure they can save it for the special cases or whatever, but there's all
these people who need it now. But, you know, they're worried about using it and antibiotic
resistance building up. So our audience seems really interested in evolution. And so we don't
need to get into it at like the molecular level. But could you talk a little bit about like the
microevolutionary process that results in antibiotic resistance? Yeah, definitely. In fact,
I think it's kind of interesting to think about, you know, just imagine a pile of bacteria.
Like, are you thinking about the fact that there's a bunch of diversity in there?
Because each cell could be a mutant.
Microbes have very high mutation rates.
So in any given population, the standing diversity is quite high.
Every time a cell copies, there could be a mutation in there.
So when we talk about antibiotic resistant cells emerging, really what that means is that you put the
selection pressure of the antibiotics onto an existing community of bugs. And some of them have
intrinsic capacity to resist the antibiotic. So those cells are the ones that survive when you give
the antibiotic. So I have a lecture slide that's in my brain right now that you guys can't see
where it's got like all different colors of circles for the different cells and some of them
are red for resistance. And that's already like that at the beginning before you even took the
antibiotic. Then when you take the antibiotic, some of those cells survive.
So that, I think, is a conceptual difference between how most of my students think it happens when I'm teaching about this.
So really, there's already resistance in the population.
And when you give antibiotics, some of the mutations that are already there help the cells resist antibiotics.
Now, how do they resist?
Some of them have pumps that can shoot the antibiotic out of the cell so they can survive.
others have mutations in a part of the cell that the antibiotic is trying to target.
So it's just like Kaping.
It doesn't do anything.
In fact, there's a really interesting diversity for the different types of ways that cells can resist antibiotics.
It's not only the classics that you read about in textbooks.
But overall, once those traits become enriched in a community, they can start to spread them to other cells nearby.
you've probably heard about like the spread of antibiotic resistance.
And it's true that bacterial cells are really good at sharing information.
They can put the information into little circular pieces of DNA
and shoot them around in the community.
And then that will help neighboring cells learn how to resist the antibiotics too.
So anyway, there's a number of different mechanisms for how cells are able to resist antibiotics.
And that's usually a trait that already exists in the population and you're just enriching for it.
first. That's really interesting. So, like, as someone who studies parasites, when we think about
resistance to drugs for parasites, you get, you know, like the hookworm that randomly is
able, for whatever reason, to resist the medication that you put in there. And then they produce
eggs that pass with the environment, and then more people get infected by this resistant to medication
hookworm. But bacteria have the additional ability to be able to share the traits for resistance
between themselves, which speeds up the rate of resistance moving through the population.
Would that be fair to say?
Yeah.
Oh, bacteria are tricky.
Definitely, yeah, big time.
They're very tricky.
Yeah, and sometimes the trait for resisting antibiotics comes at a cost.
And so if you take the pressure off and the antibiotics aren't there anymore, they'll lose that trait.
But it's interesting, sometimes the same pressures like antibiotics that help the trait stay in place can come from other sources, like in a wastewater treatment plant, for example.
example, well, there might actually be some antibiotics around, but there also might be like heavy
metals or pesticides or other kind of intense molecules that sometimes the traits that the bacteria
need to survive antibiotics can also help them survive other situations. So there's a lot of
situations in our modern world that push bacteria towards having these traits that help them
resist antibiotics. Right. I think there's a major misconception that I think you really helped
untangle a little bit there, which is that the traits are already there. It's not like the community
is seeing this attack and thinking, what can we do to defend against this? Let's brainstorm and
come up with something. It's just selecting for the folks that already have, or the bugs that
already have these traits. Exactly. Yeah. I watched that light bulb go off in my classrooms,
my whole life, where I think a lot of students imagine that you add the antibiotic, and then all
of a sudden the bacteria start mutating in this crazy new way, and then they have this.
crazy nitrate or something, but it's interesting, like, it's usually already there. It just
becomes enriched. And of course, it can get passed around, too. And what kind of infections
typically cause trouble? Are there some kinds that are more likely to have bacteria that are
resistant? Yes, definitely. In fact, there's even an acronym that the global health
organizations are constantly talking about. It's called the escape pathogens, which stands for
Eniracoccus, staphylococcus, clobacter, acinidobacter, pseudomonas, enterobacter, and sometimes we say
escapee to add E. coli. I mean, I would have guessed. I would have guessed that's what that acronym meant.
I totally have all those on the top of my head also, yeah. Let's just hope you don't put those into a
salad dressing. It sounded like a recipe. Oh, my gosh. Yeah, and there's other bugs that are not on that
list that do cause a lot of trouble that I work on in my lab, for example. Like a lot of people with
cancer and cystic fibrosis get lung infections from a bug called stenotropomonis.
Also, Berkldaria, those are gram negatives.
We sometimes call them water lovers.
You find them in tap water.
Like, they can live in tap water.
Isn't that amazing?
And they can live in soil.
So you're often exposed to them in water or outside.
And if your immune system is compromised, they can cause a lot of trouble.
Sorry, why is it amazing they can live in tap water?
I can live in tap water.
How long, though?
I mean, it's true, water will sustain a human for, like, a little while, but at some point you're going to need some calories.
And you're going to get pruny.
Oh, I see.
You mean they can eat tap water.
Like, that's their only source of calories.
That's amazing.
I see.
Okay.
Exactly.
Wow.
That is amazing.
Like, if you pick up a bottle of water at the store, it probably has some of those cells in there.
And I don't mean to make people not want to drink water because when I hear that there's microbes in something that doesn't creep me out.
I'm just like, oh, cool.
More friends.
I'm happily, you know, living a month.
them. So I'm not saying you shouldn't drink water, but it's probably true that bottled water has
higher microbial load from those gram negatives compared to like even tap water. So when we say
these infections cause trouble, do we mean that they are bad for humans or do we mean that
they're more likely to be resistant to antibiotics? Those are, well, the list I just gave you
are of common infections that are frequently becoming resistant to antibiotics in a way that's
untreatable. So for each of them, there's your annual statistics being compiled on a global level
to talk about how many infections are caused each year and how many of them resist antibiotics,
sometimes meaning you just have to switch antibiotics a few times, but eventually you find one that
works. And sometimes meaning that you literally never find an antibiotic that works. Wow. And so there
are a lot of people in the world right now who have chronic infections that they cannot clear. Like from
urinary tract infections are a really, really big one.
Sometimes lung infections, wound infections can last forever and just be very, very hard to treat.
And they're hard to get the medicine to as well because there's poor circulation in wounds.
So I hear your question, and I guess the answer is both.
Those are bugs that through human history have always caused a lot of infections.
many of them are bugs that are normal parts of our microbiome under good circumstances,
but if your immune barriers break down, which can even just mean a scratch on your skin,
like you could be a healthy person who just gets a scratch,
and then all of a sudden staff that was happily living in normal amounts on your skin
can then cause a terrible infection.
Well, I've discovered a new thing to fixate on tonight.
That's what's going to keep me up.
Let's take a break.
And when we get back, we'll talk about harnessing viruses to try to kill bacteria now that antibiotics aren't really doing the job.
Then, at 6.33 p.m., everything changed.
There's been a bombing at the TWA terminal.
Apparently, the explosion actually impelled metal glass.
The injured were being loaded into ambulances, just a chaotic, chaotic scene.
In its wake, a new kind of enemy emerged, and it was here to stay.
Terrorism.
Law and order, criminal justice system is,
back. In season two, we're turning our focus to a threat that hides in plain sight. That's
harder to predict and even harder to stop. Listen to the new season of Law and Order Criminal
Justice System on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
Hey, sis, what if I could promise you you never had to listen to a condescending finance
bro? Tell you how to manage your money again. Welcome to Brown Ambition. This is
hard part when you pay down those credit cards. If you haven't gotten to the bottom of why you
were racking up credit or turning to credit cards, you may just recreate the same problem a year
from now. When you do feel like you are bleeding from these high interest rates, I would start
shopping for a debt consolidation loan, starting with your local credit union, shopping around
online, looking for some online lenders because they tend to have fewer fees and be more affordable.
Listen, I am not here to judge. It is so expensive in these streets. I, 100%
can see how in just a few months
you can have this much credit card debt
and it weighs on you. It's really easy
to just like stick your head in the sand. It's nice
and dark in the sand. Even if it's scary,
it's not going to go away just because
you're avoiding it and in fact it may get even worse.
For more judgment-free money advice,
listen to Brown Ambition on the IHeart
Radio app, Apple Podcasts, or wherever you get your podcast.
Hola, it's HoneyGerman. And my podcast
Grasias Come Again is back. This season, we're going even
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actors, musicians, content creators, and culture shifters sharing their real stories of failure and success.
You were destined to be a start. We talked all about what's viral and trending with a little bit of
Chisement, a lot of laughs, and those amazing Vibras you've come to expect.
And, of course, we'll explore deeper topics dealing with identity, struggles, and all the issues affecting our Latin community.
You feel like you get a little whitewash because you have to do the code switching?
I won't say whitewash because at the end of the day, you know, I'm me.
But the whole pretending and code, you know, it takes a toll on you.
Listen to the new season of Grasas Has Come Again as part of My Cultura Podcast Network on the IHartRadio app, Apple Podcast, or wherever you get your podcast.
Your entire identity has been fabricated.
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Listen to Family Secrets Season 12 on the IHeart Radio app,
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Okay, we're back, and Kelly is covering herself with bubble wrap to protect herself from the future of infections.
I can't imagine a chronic UTI. That sounds awful.
It does sound awful, doesn't it?
Katrina has a salad dressing that'll fix that for you.
Oh, my gosh.
Oh, that's great. That's great. Or cranberry pills or something. But anyway, all right. So we talked about how antibiotics are not working anymore in a lot of cases. And so you work on phage therapies. So what is a phage?
Phages are viruses that kill bacteria. And so just to back up, for every cell that we have on the planet, there's usually about 10 kinds of viruses that can infect it. So there's always viruses around that can infect every kind of cell. Like that peasant.
pepper or tomato on your plate, there's tons of viruses that can infect that. So similarly, for all
of the bacteria that we've talked about, there's usually about 10 viruses or so that can infect
that cell type. So the idea of phage therapy is to take the viruses that can infect bacteria
and use them as a medicine, kind of like the enemy of my enemy is my friend. Do the viruses
have viruses? Yeah, well, there's actually, maybe they do, actually. There's,
There's kind of little hitchhiker DNA pieces that could be considered viruses on viruses.
So, yeah, it never ends.
Okay.
And should we think of these viruses the way we think of our microbial community?
Like, are they sometimes helping the bacteria, sometimes it's not so clear, sometimes hurting them, or are they always invading and taking over?
Is it always a negative relationship between the viruses and the bacteria?
It's definitely not always negative.
And I think one of the big lessons of the last few years of our field is that it's pretty hard to categorize.
categorize them. There's more of a gradient, so there's sometimes very direct killing types of
relationships, but there's also a lot of kind of infect and hang out for a long time kind of
relationships. And the truth is, there is no bacterial community in the world that doesn't have
viruses in it. So we can't really talk about what it would mean to be a bacterial community
without viruses. They're just part of the situation, you know. Viruses are here to stay,
you're saying. They're here to say, and they're a big part of how bacteria work. I mean,
And anytime a bacterial community experiences some kind of stress, they're going to be enriched for the cells that can handle the stress.
And viruses are going to be transmitting the information to help them do that.
So a big part of how bacteria can adapt to new situations is that the viruses help them out by transmitting information.
I don't know how to feel about this.
At first, I was like, bacteria are a pathogen.
They're hurting us.
They're killing people.
They're painful UTIs.
Now you're talking about them experiencing stress.
And I'm like sympathetic towards them.
And so, like, what am I supposed to feel about bacteria, Katrina?
I mean, most bacteria are not pathogens, like, by far.
Like, I just named a couple bacteria that cause infections,
which actually are usually healthy, normal parts of our communities.
And then that doesn't even begin to talk about all the microbes in the world.
Very fewer pathogens.
It's just the ones on the news are pathogens.
They should write more positive stories about helpful microbes.
Yeah, they should.
I do see a lot of them, although they're not very good scientific.
But always. But okay, so if every bacteria has 10 viruses, does that mean that viruses are the most, like, diverse and specious life on the planet? Or is, are the same viruses infecting lots of different kinds of bacteria?
They are by far the most diverse. That is exactly the thing to say. I mean, I've got all, like, there's so many cool analogies. There's more viruses than stars in the galaxy or grains of sand on the planet.
I think it's 10 to the 31. If you lined them up head to head, they'd go to the edge of the galaxy back and forth a bunch of times. You know, it's a crazy number of viruses. Yes, they are super, super diverse. And you asked a really important question about how specific they are. Like, is a virus that infects one of those bugs, the pseudomonas, also able to infect a different bug, the Staphylococcus, or something like that? Typically, no. In fact, it's at a substrain level. Like a phage that infects one pseudomonas, also able to infects,
What's a substrane?
It's like a subtype of pseudomonas.
Like any type of bacteria has genus and species names.
You know, Kings play chests on fine-grained sand, the taxonomy going down to genus and species.
Oh, you learned a nice one.
Yeah, there's probably less appropriate ones going around the school yard.
Yeah, yeah.
I won't repeat mine.
Go ahead.
And so there's even substrines.
So like pseudomonas originosa is a genus and species name, but there's some.
subtypes beyond that, and whether the phage infects is usually at a subtype level like that.
And it's kind of interesting to think about it. I mean, the bacteria are constantly making small
mutations to resist the phages. So the trait of resisting a phage turns on a dime. It's just
one mutation can probably do the trick. So it's not like a big complicated trait, like using
oxygen and then you would need like a whole bunch of different genes and it's like very
conserved and if you looked back in the history of bacteria you'd see big movement towards like
oh now they can use oxygen or something like that phage infection is like a tiny little thing
it's very easy to change it it's at the tippy tippy branches of the toxinomic trees and so if
there are all these viruses out there that are infecting bacteria and they're very specific to
the bacteria but a very small change in the bacteria can mean that they can't be infected by the
viruses. Is there some vast ocean of viruses out there that can't infect any bacteria yet
and some mutation of the bacteria makes them therefore susceptible? Or do viruses only exist
and propagate if they can use bacteria? Well, I think there is an ocean of viruses out there that
never get to infect a cell. So they have kind of an unrequited dream of finding a host and they just
never do. However, the dark viruses. Yeah, the lonely ones. But now you're
You're making us sympathetic to viruses, Katrina.
You were too empathetic.
So, yes, there's going to be viruses out there that never get to infect a cell.
But the strategy of a virus is to make a bazillion copies with lots of variation and hope that several of them have the capacity to go and find a host in a changing world.
It's like, and rather than training one kid with lots of skills and hoping they'll find a job in a changing world, it's like.
like you've got to raise billions of viruses and a few of them will continue to be able to infect.
And I mean, it's been going on for a long time and in a way it's quite stable.
Like if I took samples from anybody listening to this podcast right now and then in five more years
took another sample, most of the gut viruses would still be there.
They might have evolved even one to three percent of their genome could have changed in a new direction.
but I would be able to recognize them as themselves.
So it's not like it's this raucous thing that's turning over
and becoming a totally different thing all the time.
There's some stability there, especially within the individuals.
Each of our guts is like a little chemistat
with tons of virus and bacterial evolution happening all the time.
And it drifts around a bit, but it's quite stable in some ways.
So we are like the interlopers, the weird ones in a viral world, right?
That's certainly one way of looking at it.
I think we have some advantages. I think consciousness does have, does distinguish us from viruses.
There's days when I'd rather not have consciousness. But anyway, okay, so we've got viruses and some of them are bad for bacteria.
How do we harness that to fight bacteria?
So basically, the way that phage therapy has worked since even before we had antibiotics, so we've been doing this, phages were discovered in 19.
Or 1915 or 1917, depending how you look at it.
And what we do is if you have a bacteria causing an infection, you use that as a hook and you go hunt for phages in a sample that has a lot of microbial activity to it.
Wastewater is a popular place to hunt, but freshwater ponds, puddles in front of your building.
Wastewater is such a euphemism. I mean, you're talking about poop to pills, right?
We're like finding medicine in sewage.
Sewage is such a concentrated way to grab the microbes of humanity that it's a very tempting place to look.
Yes.
Because it's going to represent a lot of people.
Like when we were doing our wastewater sequencing project during the pandemic, we were getting eight samples per week from Southern California wastewater treatment plants that represented 16 million people.
Wow.
From just eight samples.
You are the queen of silver linings.
Sewage is so tempting, said nobody ever.
Anyway, maybe we're not going to put you in charge of marketing and flavors for the new salad dressing company.
So you're saying you have a bacteria, you're looking to target, then you go out and you search extent communities of viruses and you're trying to find one that will kill this particular bacteria?
Exactly.
So you take the infecting cells, you mix them with some wastewater, and then we use a technique.
I mean, I need slides, man.
This is hard on a podcast, but I want to show you guys pictures.
Yeah, it is.
But, you know, you make a plate of the bacteria mixed with the material that you hope has phages in it.
And an important thing to say is that we filter it.
We try to get the cells out of there, so it's just viruses left behind.
because otherwise you might imagine everything
from the whole wastewater treatment plant growing on your plate
but actually you filter
and hopefully there's viruses in there that infect your cell
but it's a mystery every time
sometimes we spend six months hunting for a phage for one strain
even though I've got like really good people
with lots of experience and I've got tons of great wastewater
I'll tell you that.
So it's sort of like you have a lock
and you're putting it in a bag of keys
and shaking it around and hoping one of them goes in.
Yeah and then then you get more experience
with knowing what kinds of wastewater treatment plants are enriched for the bugs you care about.
Like, for our Steno-Trimonus project, the wastewater in Escondido is, like, amazingly good.
So if I get a steno infection, I'm like telling the students, please get the Escondido wastewater.
What are they eating in Escondido?
Or is it because of, like, an agricultural influence, or I don't know.
I would love to know the answer to that, but I can tell you it's been true for years and lots of other labs
failed to find Stenotropomones phages.
But when we use Escondido wastewater, we've even sent our Eskondido.
into wastewater to collaborating labs, and they've also succeeded.
It's liquid gold.
Yeah. So then once you, if you're lucky, and you'll come in in the morning and you'll see a
white bacterial lawn, and then you'll see these clearance zones on the plate. Those
represent the phages. So if you get one of those, then you have a manufacturing project
on your hands. Then you have to get the phage into big enough amounts and clean enough amounts.
Wait, back up and explain what you were talking about there. A white bacterial lawn?
Mm-hmm. So you'll have a plate of bacteria that look white. So you'll have like a flat white background.
Why do they look white? Well, some bacteria are a little bit yellow or most bacteria are white or yellow.
Sometimes they turn a little blue. But the point is you have a clear growth of cells on your plate.
And then you can see with your naked eye that there are clearance zones from the viruses. And so that represents, if one virus infects one of the cells on that plate, it will keep representation.
replicating and chewing up and eating and breaking the cells.
So you'll get a clearance zone that's visible to the naked eye.
I mean, obviously one virus is not visible to the naked eye, but what is visible to the naked eye is it's called a plaque.
And it's a bunch of cell death caused by the virus in one little zone of the plate.
And you can see that.
And how do you know which virus has done it?
You don't.
You just know it looks like a virus.
And if you've done it for a long time, you start to get familiar with the way the shape.
in the size of the plaque, the clearance zone, you can usually distinguish it from an air bubble
or something like that, but not always. So it's definitely still an identification project once you
get the plaque. But that's kind of step one. So really in my lab, if someone sends us,
every week or two, we get a new isolate into our lab where a doctor has a patient who has an
antibiotic-resistant infection and they want to know, do we have a phage? So the first thing we do
is we reach into our freezer,
where we already have about 200 phages,
and then we'll see if one of the ones that infected a similar strain
can infect this new one.
That's the easiest answer,
because then we'll have already sequenced it.
We'll know what it is.
It's a big head start.
But it's not uncommon, I'd say easily half the time,
that none of the phages we have can infect.
So then we do a new hunt in wastewater.
And you have like your own personal lab library,
like the ones you're talking about in your freezer,
there's another lab somewhere else
they have a different set
and another lab has a different set
this is like Katrina's personal phage arsenal
that's right yeah
and it's the way that you protect
the information is really complicated
and we're all everyone's always
changing their mind about that
my general attitude has been to be very open
and if somebody at another university
needs one of our fages I just send it to them
but we could be shooting ourselves
as a community all in the foot
because we're removing the capacity
to make money off of them
so then nobody would ever invest
and what we need is for like real investment to get this thing off the ground, you know.
All right.
So back on the process here, you have the isolate, you scan through all your phages by just
like mixing them together and seeing if one of them kills your bacteria.
Maybe you have to go out to Escondido or somewhere else to find more phages.
But now you have one that you think kills the bacteria.
What do you do next?
Then we purify.
We have to like continue propagating and purifying.
Most phage preps are contaminated in some way.
it's actually very hard to get a prep that has just a single phage in it
because they come out of these communities with a lot of different members.
So step one is propagating where you pick the plaque
and you infect bacteria and it's like a 24-hour project each time
and you do that easily like three or four times.
And some phages will kind of peter out at that point
and reveal themselves to be hard to work with.
And so if you have multiple different types emerging,
on your plate, you just abandon the ones that are difficult to deal with because what you want
are easy to deal with fages.
Difficult to deal with?
Like, they send grumpy emails late at night or what's going on?
Like, one day they make a beautiful plaque and then the next day, even though you did everything
exactly the same way as far as you know, it just doesn't do anything.
And then you're like going back to the plate from two days ago and hoping you can get it
to cooperate again, that kind of thing.
It's biology, so it depends.
Yes.
And by beautiful plaque, you mean like one day it beats the heck out of the
bacteria and the next day it doesn't seem to kill them at all? Yeah, like maybe you'll get a nice,
big, visible plaque, which means it's easy to pick so you can get material to work with for the
next day. And then the next day, your plate has nothing on it. So you're like, where did it even go?
So each time you're picking the viruses that killed the bacteria and putting them onto a new
plate. Exactly. And hoping to get a pure culture eventually. Exactly. And then you find out all these
finicky things about how to deal with them. Some viruses prefer to grow in liquid. Others prefer
to grow on a solid plate.
Others do really well when the cells are multiplying quickly.
Others do better when the cells are like kind of overnight growths that got tired out
and we call them stationary phase.
You know, they're like not as actively growing anymore.
And viruses have all different mechanisms of entry and preferences for metabolism.
So all of those things, you don't know them about your new virus yet.
You're just like trying to propagate it.
So then we'll do all kinds of things where we'll,
do temperature gradients and different types of media growth. And we'll try like triangulating all
the conditions to learn what this particular virus likes the best. So then we can do a better job
of propagating it in successful conditions. All right. So we've learned how to make a virus happy.
And when we get back, we'll talk about actually giving those viruses to people.
December 29th, 1975, LaGuardia Airport.
The holiday rush, parents hauling luggage, kids gripping their new Christmas toys.
Then, at 6.33 p.m., everything changed.
There's been a bombing at the TWA terminal.
Apparently, the explosion actually impelled metal, glass.
The injured were being loved.
Loaded into ambulances, just a chaotic, chaotic scene.
In its wake, a new kind of enemy emerged, and it was here to stay.
Terrorism.
Law and Order Criminal Justice System is back.
In season two, we're turning our focus to a threat that hides in plain sight.
That's harder to predict and even harder to stop.
Listen to the new season of Law and Order Criminal Justice System on the IHeartRadio app,
Apple Podcasts or wherever you get your podcasts.
Hey, sis, what if I could promise you you never had to listen to a condescending finance, bro, tell you how to manage your money again.
Welcome to Brown Ambition. This is the hard part when you pay down those credit cards.
If you haven't gotten to the bottom of why you were racking up credit or turning to credit cards,
you may just recreate the same problem a year from now. When you do feel like you are bleeding from these high interest rates,
I would start shopping for a debt consolidation loan, starting with your local credit union, shopping around online, looking for some online lenders because they tend to have fewer fees and be more affordable.
Listen, I am not here to judge.
It is so expensive in these streets.
I 100% can see how in just a few months you can have this much credit card debt when it weighs on you.
It's really easy to just like stick your head in the sand.
It's nice and dark in the sand.
Even if it's scary, it's not going to go away just because you're avoiding it.
And in fact, it may get even worse.
For more judgment-free money advice,
listen to Brown Ambition on the IHeart Radio app, Apple Podcasts,
or wherever you get your podcast.
Hola, it's Honey German.
And my podcast, Grasias Come Again, is back.
This season, we're going even deeper into the world of music and entertainment,
with raw and honest conversations with some of your favorite Latin artists and celebrities.
You didn't have to audition?
No, I didn't audition.
I haven't auditioned in, like, over 25 years.
Oh, wow.
That's a real G-talk right there.
Oh, yeah.
We've got some of the biggest actors, musicians, content creators, and culture shifters
sharing their real stories of failure and success.
You were destined to be a start.
We talk all about what's viral and trending with a little bit of chisement, a lot of laughs,
and those amazing Vibras you've come to expect.
And of course, we'll explore deeper topics dealing with identity, struggles,
and all the issues affecting our Latin community.
You feel like you get a little whitewash because you have to do the code switching?
I won't say whitewash because at the end of the day, you know, I'm me.
Yeah.
But the whole pretending and cold, you know, it takes a toll on you.
Listen to the new season of Grasas Has Come Again as part of My Cultura Podcast Network on the Iheart radio app, Apple Podcasts, or wherever you get your podcast.
I had this, like, overwhelming sensation that I had to call it right then.
And I just hit call.
I said, you know, hey, I'm Jacob Schick.
I'm the CEO of One Tribe Foundation.
And I just wanted to call on and let her know there's a lot of people battling some of the very sane.
things you're battling, and there is help out there.
The Good Stuff podcast, season two, takes a deep look into One Tribe Foundation, a non-profit
fighting suicide in the veteran community.
September is National Suicide Prevention Month, so join host Jacob and Ashley Schick as they
bring you to the front lines of One Tribe's mission.
I was married to a combat army veteran, and he actually took his own life to suicide.
One Tribe saved my life twice.
There's a lot of love that flows through this place, and it's sincere.
Now it's a personal mission.
Don't have to go to any more funerals, you know.
I got blown up on a React mission.
I ended up having amputation below the knee of my right leg
and a traumatic brain injury because I landed on my head.
Welcome to Season 2 of the Good Stuff.
Listen to the Good Stuff podcast on the IHeart Radio app, Apple Podcasts,
or wherever you get your podcasts.
Okay, we're back and we're hearing about how Katrina's lab,
might save somebody who's out there with a really difficult infection, whose doctor emails her
and asks her if she's got something cooking up in the freezer that can kill their bacteria.
So we've heard about how you find a phage that can help infect your bacteria.
You purify it, you isolate it.
How do you actually go all the way to putting it back into human and treating them?
Well, that's a really big question, but it's actually an old question.
So since around 1920, especially in the former Soviet republics, phages have been used as medicine since before we even had antibiotics.
And they were actually used in the Western world, you know, before the era of World War II as well.
Like, for example, when Elizabeth Taylor was filming Cleopatra, I think she was in the UK, she got a terrible staff infection, and they used phages to help clear her infection.
There's a lot of stories like that from around that time.
And so at the Eliava Institute in Tbilisi, Georgia, which is probably the most famous of these centers, they've been using phage therapy to treat infections for more than a century. And so it's the process like I just told you about. They have a much bigger bank of phages than I do, I'm sure, but they will find a phage. If one of their standard ones doesn't work, they'll go find a new one, and they prep it and give it to you. But in the United States, there is
no approved way to use phages. It's not sold. There's no FDA approved medication that your doctor
can prescribe. So all of it is happening through labs like mine and through applications to the
federal drug administration asking for an exemption, either as an emergency authorization or as a
compassionate use exemption. So it has to be a situation where somebody's in really dire straits
and taking on the risk of an experimental treatment makes sense.
So in my lab for many years, I've been growing up these fages out of wastewater,
and people were sometimes sending me their patients isolates and asking if we had a phage.
And we almost always succeeded.
That was not the barrier.
But usually the person would either get better or pass away before we could get the phage prepped in order to help them.
And that went on for years.
And every time I would have a student who was such a good spirit and would spend the whole weekend,
working really hard to get the phages and we'd be like so proud of the fact that we had one,
but then it wouldn't actually help anyone because the whole process is too slow to help someone
in really dire straits. So about a year ago, I went to the infectious disease department Grand
Rounds at UC Irvine where I work. And I talked to all the doctors about it and I got a lot of
help from Jessica Satcher of the phage directory. This was her idea, I think, actually. And we talked
about how we should aim for people who are not quite so acutely ill. People who have a more
chronic infection where their life would change and be improved if we could help them, but where
if it took us like six months or a year to get all the approvals and to prep the phage,
that would be okay. So that was April 2024. So since then I've had 10 cases. We found phages
in every single one, but only once have we gotten all the way to the like FDA approval and
actually give the phage to a person's step.
And it's all thanks to a student named Ritwick Kumar.
He's really the reason this all happened.
So he personally found, well, with a team of other students and a medical resident who joined our lab as a volunteer, actually.
Ritwick hunted for a staff phage for the patient I'm talking about for about six months and never found one.
Then the first week, our new medical resident, Alexandra, showed up.
She found a phage.
So there must have been something different about her technique or the patch of waist.
water we used that week or something.
Anyway, we got a wonderful staff phage.
We named her Ludmilla.
And Alexandre named her Ludmilla.
And so since last summer, we have been prepping this phage Ludmilla to help a patient
at the UCI Medical Center who has a chronic sinusitis with MRSA, metacillin-resistant
staphylocococcus aureus in their nose.
And the doctor felt that it was a good case because the patient...
is getting frequent fevers, and so their quality of life is very affected,
but they're stable enough that if we took six months or a year, it would be okay.
And that is how long it took.
So I actually sent Ritwick to my friend Dari Van Tynes Lab at Pitt to learn how they prep the phages
because we were a little new at it, and I wanted to make sure that we were getting good advice,
and he could watch somebody else doing all the steps.
And then we also chose a gram-positive bacteria, staphilococcus,
because it doesn't carry endotoxins,
which are really hard to purify out of bacterial preps.
So it kind of made the process simpler
by starting with a gram positive.
Anyway, so Ritwick made a big batch of these phages.
He stewed up some Ludmilla soup.
He stood up some Ludmila soup,
and then he filtered out all the stuff that could cause trouble.
And, I mean, I probably should not go into so many details about the protocol,
but ask questions if you're interested.
And so we prepped up the phage in a safe way.
And then we actually even sent it out to a third-party lab to test for sterility and endotoxin.
Because I didn't want it to be just like, yeah, me and my students think this is really clean.
I wanted it to be like official, you know.
And that's actually required by the FDA as well.
And so once we had all that stuff done, we made this 50-page document and sent it to the FDA asking for authorization to use the phage.
Actually, it was very interesting.
Initially, we wanted to use the phage in an IV form.
and the FDA came back and suggested instead that we do a sinus rinse,
which I think was a really smart move because there's less chance for immune reaction.
I don't have high expectations of problems with this, by the way.
I mean, beyond the Eliava Institute's century of experience, now in the United States,
there's been several hundred cases in the last couple years,
and I'm not aware of any adverse events.
And by that, you mean nobody's had like a weird immune response to getting viruses put in them,
like everybody's fine. Maybe it doesn't kill the bacteria, but it doesn't hurt the people.
Exactly. The person doesn't have a negative reaction to the treatment so far. I mean, it's still
experimental, but so far there haven't been people having negative reactions. Great.
What an amazing bespoke process, though, like a lab with a student focused on one patient for months and
months and months. What a huge process and all this application. All right, so tell us what happened.
Did Ludmilla help?
Well, I don't know yet. Yesterday, it's been three weeks. So it's a six-week treatment process. So it's daily sinus rinses for six weeks. Good news. Nothing bad has happened. But really we won't know. I mean, I think it's possible that they're feeling a little bit better. But they're also getting antibiotics at the same time. So the moment of truth will come about three to four weeks after the six weeks treatment. Because usually after the antibiotics are stopped, the fever.
come back. So we're going to wait to see if the fevers do not come back at the end of the six
weeks. All right. Well, we're recording this episode in mid-August, but we're going to post it later.
So just before it posts, we'll get an update from Katrina on how this is going. So listen at the end
of the episode for a more recent update from Katrina. Oh, what a good idea. I'm excited.
But there's, I mean, there are actually a lot of interesting cases to follow. In fact, I was at the
Evergreen Fage meeting in Knoxville, Tennessee last week. And I met
a man who's been coming to the meeting a couple times, who had a really terrible ecoli infection.
And he actually traveled to the Elie Ava Institute in Tbilisi, Georgia, where they do these phage
treatments. They cooked up a specific phage just for his infection, because none of the ones in
their bank were effective. And the doctors there had him do three, 20-day courses of three
times a day phage treatment. And it wasn't until the second 20-day course that he's
started to feel better, and then his bacterial load and his blood dropped. So it's not necessarily
that you would see a big effect in the first couple weeks, like in his case, at least it
took several times. And he wrote a book about it. He's been on a lot of podcasts. It's a really,
really cool story. So it's so cool that it worked for him. And if you look at the summary of some
of those hundreds of cases that have been going on lately, it looks like 75 to 80 percent of
people have a positive response as in like their infection is helped.
Wow. But it's still very early days. I mean, as you say, Daniel, it's like kind of crazy to imagine that there's an individual lab customizing a treatment to each person. But on the other hand, the skills it takes are not that crazy. Like, I don't understand why we wouldn't have phage therapy clinics to be able to do this for people. Like, the resources are not that intense. The know-how is, you know, something that a good student can learn how to do.
And we've known about this for 100 years. There's an institute in Georgia. Why isn't it?
more common? Like, why doesn't the U.S. allow this to happen all the time?
I think it's a medical history question. I think we just went down a road using antibiotics
and they were approved into the medical system that we have. And it's a very different system.
For antibiotics, there's a few dozen molecules. So it's possible to approve each one of them
in a trial that these days would cost $100 million to get a drug through a phase three
clinical trial. You can't really do that for every single phage, obviously. It's possible that the
FDA will approve the preparation methods that we use, and then that would work for multiple
different kinds of phages. But using the model of clinical trials that we currently have for
approving drugs won't work for phages because you need different ones for each infection.
So that's the real reason that it's not happening as much right now, I would say.
How do you see it scaling up? Like, is there a future in which?
which people have individualized medicine, where I don't need Katrina and her lab, like,
working on me individually. It's like roboticized or automated or how do we make this more
widespread? It could be that we can develop evolve or engineer phages that have broader
host range so that we would only need a relatively small number of phages to cover most common
infections. So that is certainly one possibility. That's a science question. I don't know if that's
possible or not, but like in my own lab, we often do experiments where we evolve our phages
to try to have broader host range to be able to infect more different subtypes of the same
bacteria. You could also use molecules to try to assist the infection, and that might make
one phage work in more context. Those are like two main research areas in my lab, actually.
So that's possible. That's still a science question. But then even just using exactly the model
of the Elieava Institute.
I really love that idea.
I just don't know how it would work
in our current health care system.
Maybe it has to be more like
the way that supplements are sold,
where they're generally regarded as safe.
And so people could use phages
as a kind of augment,
like an addition to their antibiotics.
Uh-oh, are we walking towards
the podcast supplement industry
that so many people get sucked into?
We are not peddling supplements here.
I was thinking more like a, I think like a wellness spa.
Like, apparently the Liyov Institute is an integrative health center where you get a massage every day and you meet with a team of doctors and psychiatrists and everybody helps you get better.
And so.
Heck yeah.
Exactly.
So, like, hey, we're in sunny SoCal.
Maybe we should make a clinic.
Some of us.
Yeah, that's right.
Can we talk a little bit more about the trade-off?
So you were talking about how your lab is trying to evolve the phages to be able to attack more kinds of bacteria.
So two thoughts. One thought is that we talked earlier about how each phage is usually specialized on one species or even strain of bacteria. So I imagine it's very hard to evolve it to be more of a generalist. And then two, you know, one of the benefits of this technique to me seems to be that you don't wipe out the rest of your bacteria. You can like maintain your microbiome and just target the bad guy. Yeah. So like what are what are the tradeoffs with trying to make a more general phage?
Well, a more general phage would likely still be way more precise than an antibiotic. So if you were to take a phage that can kill most of your enterococcus fecalis or pick one of those escape pathogens, that would still leave tons of other bacteria alone in a way that antibiotics really never do. So I think it would still be way more specific, even with a more generalist phage.
Cool. So then the question is just whether we can evolve those generalist phages. For some industrial applications, there has already been signs of success for that. Like, in fact, the deli meat industry and the food spoilage industry have been using phages for a long time. And I think that there's a lot of industrial know-how that I am not privy to that suggests that this has been possible. So I don't know, but I think that there are a handful of staphiloc
Caucasus and Listeria and phages that are used in the food industry that actually do have pretty
broad host range. So it could be that we could use the same methods to make that happen for human
medicine too. But there's still, it's just a totally different regulatory framework than what we're
used to for pharmaceuticals. So it's an interesting thing. I'm so curious if in 10 years we're going to
have this all figured out and it's going to be widespread or if it's still going to be this kind of
backwater. It's hard to know. It feels like there's a sea change right now, that there are now
hundreds of clinicians that are very interested. But on average, if you go to your doctor and
ask about phage therapy, they're probably not going to have heard of it, you know, or not know
much. And in that scenario, could phage therapy be a victim of its own success? I mean, if you
have these phages, you start using them on bacteria, are you then just going to end up with bacteria
that are resistant to your phages? Couldn't it suffer the same fate as antibiotics? Yes, bacteria
will evolve resistance to the phages, and that's exactly the same problem we have with
antibiotics, you're right? I guess I look at it like the bacteria and phages have been in these
arms races through the ages, and what you're trying to do in an infection is to give the immune
system a leg up, and so in an acute sense, what you need is like a one-two punch, and you could
use antibiotics and phages at the same time, and you get in there,
and you tap the infection down a bit,
and you just give the immune system a moment of breathing room
so that there's more chance for the human to survive the battle, you know?
So, yeah, it's true that there could still be resistances arising to phages.
But when people use that argument, I'm always like,
hey, well, antibiotics, you know, bacteria-resist antibiotics too,
and that didn't stop us from making good use of them
and figuring out treatment plans that set things up
so the human can succeed.
So I think we just need to learn how to do that, which is very early days.
As you can imagine, we've only used phages like, you know, a couple hundred times probably in the United States in the last decade.
So it's not like if people ask you questions like, oh, should we use this dose or that dose or this treatment time or that treatment time?
I mean, we do not know the answer to things like that yet.
There's a final question we have to ask, which is, are there bacteria in space with phages and are aliens using phages?
Phage therapy. How would you phrase the alien question this time around, Daniel?
No, I've trained you well, Kelly. That was perfect. Yeah. Do aliens have viruses, Katrina?
Well, am I in the Whiteson Institute now? Yes. Yes. We'll send you some salad dressing, yes.
Oh, my gosh. Well, we definitely have brought Earth's microbes out to space, although there is a whole
division of NASA aiming towards preventing that from happening. So we work hard not to, but microbes
are everywhere. So of course, we've brought some out to space. So there's definitely going to be
some phages out there, would be my guess. I mean, they're probably not going to survive long. So
would they make it to where aliens are? I would say no. No, but would aliens have their own
native viruses? Do you think viruses are a common feature of life everywhere in the universe?
Yes, I definitely do. I mean, I think most life will start from little,
self-replicating things like RNA world. I mean, that's the only model in my head. So, of course,
I need to meet an alien who has a different model in their head to contradict it. But I could
imagine a totally different type of life emerging with the same order of events where you start more
from little self-replicating things that essentially are viruses. And in general, yeah, it's hard
for me to imagine an ecology that doesn't have infection and viruses going on. So then actually my
last question, Katrina, is where do your sympathies lie? I mean, you are growing up these
phages. You're attacking the bacteria, but you're also talking about the bacteria, getting stressed
out. Are you in the camp of the humans or the bacteria or the viruses? Really, where should we
put your allegiance? I mean, I do not think you need to have separate allegiances. This is like a big
team. Dodging the question. No, she's not. That's a perfectly valid answer. Okay, but here's
what I'm saying. I think that the bacteria are invited when they are behaving themselves. I mean,
I am not inviting crazy infecting drug-resistant bacteria. Those guys have gone too far, you know.
So there are some limits to Katrina's empathy even. That's amazing. But like an average bacteria is not a
pathogen. But yeah, the pathogens, they're like nihilists, you know, they're not invited. Amen.
All right. Well, it has been a fascinating day here at Daniel and Kelly's viral universe. I always love having you on the show, Katrina. Thank you.
Well, thank you for having me. And thank you guys for listening to phage therapy. And if your listeners have any suggestions about how our community should get phage therapy off the ground, we're really listening.
All right. So it's August 25th. And we're checking in for an update on that patient. Katrina, what is the status of the patient that you're.
your lab developed a phage four? Well, it's week four out of six now. So the fifth week of treatment
out of six will begin on Thursday. So we don't have any knowledge yet of whether it worked. We actually
have to wait for a month after the end of the therapy to see whether the fevers return or not.
And that's how we'll know whether the staff causing sinusitis in the nose has been dampened
and hopefully taken out by this phage. All right. Well, because we're going to have to have
you back on the podcast for a follow-up episode to see how this stuff works.
I would love that. Great idea.
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