Assessing the extinction risk of all species of freshwater fishes globally

Bagarius vegrandi © Nonn Panitvong.jpg

Assessing the extinction risk of all species of freshwater fishes globally: an interview with Catherine Sayer

Catherine Sayer is the Freshwater Programme Officer in the IUCN Biodiversity Assessment and Knowledge Team, based at The David Attenborough Building in Cambridge, UK. She is currently working to get the extinction risk of all species of freshwater fishes globally assessed for the IUCN Red List, which will fill in knowledge gaps on which regions have the highest numbers and proportions of threatened freshwater fishes, giving a greater understanding of where conservation programmes are likely to have most impact.

SHOAL caught up with her to learn more about the IUCN Red List assessment process and get some advice on how researchers and taxonomists can conduct Red List assessments themselves.

Tell us a bit about your background and your current role. And what led you to do what you do now?

I have been working for IUCN since 2014 based in Cambridge, UK in the (recently renamed) Biodiversity Assessment and Knowledge Team, part of the IUCN Centre for Science and Data. I was initially part of the Red List Unit, but since 2016 have been focussing on freshwater biodiversity, now with the role of Programme Officer.

My background is quite broad, with an undergraduate degree in Natural Sciences (Zoology) and an MSc in Ecology, Evolution and Conservation, but over the last few years I’ve become much more familiar with the fascinating and often overlooked world of freshwater! At present, my work primarily focusses on increasing the representation of freshwater species on the IUCN Red List of Threatened Species™, through assessment of species of freshwater decapods (crabs, crayfishes, and shrimps), fishes, molluscs, odonates (dragonflies and damselflies), and aquatic plants. This is important given the unprecedented level of threat to the freshwater realm, which is incredibly species rich (supporting over 10% of all known species and 30% of vertebrates, despite covering less than 1% of the Earth’s surface), and of great value to human livelihoods in terms of ecosystem services.

Catherine Sayer © Catherine Sayer
Catherine Sayer © Catherine Sayer

You have recently done a gap analysis to see which species still need to be assessed for the Red List. What does this involve?

IUCN is working to complete a global assessment of all freshwater fish species for the IUCN Red List, and I recently completed a gap analysis to identify which freshwater fish species still need to be assessed. To do this I compared a list of all described freshwater fish species from Eschmeyer’s Catalog of Fishes, which is the standard taxonomic source for fishes on the Red List, to a list of all species with assessments published on the IUCN Red List, or under way through ongoing projects. The resulting list (after accounting for quite a few taxonomic discrepancies and changes!) includes all “gap species” of freshwater fish that still need to have Red List assessments completed. Many of these species are those that are relatively new to science, having been recently described, such that our target list is growing as researchers and taxonomists identify and describe more species!

And what does a Red List assessment involve?

An IUCN Red List assessment tells us the relative extinction risk of a species. Each assessment includes an account with information on the distribution (including a distribution map), population, habitats and ecology, use and trade, threats, and conservation and research actions relevant to the species. This information is then used to assign species to a category of extinction risk based on data driven and objective criteria. The criteria are designed to identify species at higher relative risk of extinction based on their population size, population trend, or geographic range, together with information on threats acting on the species. Species assessed as Vulnerable (VU), Endangered (EN), or Critically Endangered (CR) are described as threatened. However, the Red List isn’t just limited to those species at high risk of extinction – it includes information on all species that have been assessed against the categories and criteria, including those assessed as Least Concern (LC) and considered to be at low relative risk of extinction, for example.

We work with species experts and conservation scientists to draft Red List assessments based on the best available knowledge at the time of assessment. Anyone with knowledge of the global population of a species can be an assessor, but in practice most assessments are drafted by members of the IUCN Species Survival Commission (SSC) Specialist Groups. Once drafted, assessments are reviewed by independent experts to ensure the data presented are correct and complete. Prior to the COVID-19 pandemic, these first steps (drafting and review) often took place in workshops where we gathered species experts to assess the freshwater species native to a particular region and/or taxonomic group, but at present assessments are completed remotely by individuals or groups of experts collaborating online. Once reviewed, assessments are submitted to the IUCN Red List Unit in Cambridge, UK for final consistency checks before being published on the IUCN Red List website, which is recognised as an online scientific journal.

Once published, IUCN Red List data are available for many uses by a number of sectors: education and public awareness, scientific analyses, influencing conservation policy, informing conservation planning and priority setting, assisting with private sector decision making, and more. To search for a species on the IUCN Red List, simply enter its scientific or common name into the search bar at the top of the website. If the species has been assessed for the Red List, you will be taken to its species account.

Workshop group photo © Catherine Sayer
Participants of the Sunda Basin Freshwater Fishes Red List Review Workshop held at Wildlife Reserves Singapore, Singapore in January 2019. © Catherine Sayer
Screenshot of IUCN Red List assessment
Screenshot of IUCN Red List assessment

Approximately how many freshwater fish species are assessed each year?

On the current version of the Red List (version 2021-3), there are assessments of 11,291 species of freshwater fish, representing over 60% of all described freshwater fish species. This total is the result of over 20 years of Red Listing work, but efforts and number of species assessed have greatly increased in recent years with support of initiatives such as the IUCN–Toyota Partnership, which have enabled us to increase the geographic coverage of the Red List with respect to freshwater fishes. In 2020, assessments of close to 1,800 freshwater fish species were published, primarily from the Sunda Basin and New Guinea, and in 2021, assessments of over 900 freshwater fish species were published, including species from Brazil, the Caribbean, and the Philippines. This year, we are hoping for many more species to be published, the majority of which will be native to South America.

And approximately what percentage of these are threatened with extinction?

Of the freshwater fish species assessed for the Red List so far, a best estimate of 30% are considered to be threatened with extinction, meaning they are assessed as Vulnerable (VU), Endangered (EN), or Critically Endangered (CR). This estimate isn’t yet based on complete data (given all freshwater fishes haven’t yet been assessed for the Red List), but indicates a higher percentage threatened with extinction than for birds, reptiles, and mammals, all of which have been assessed. Of the threatened freshwater fish species, 636 (6% of the total) are assessed as CR, and 943 (8%) are assessed as EN. It’s also important to note that a high proportion (21%) of the freshwater fish species assessed so far have been categorised as Data Deficient (DD). This means that there is insufficient information available to indicate their relative extinction risk, bringing some uncertainty into these estimates.

Nothobranchius elucens © Béla Nagy
Nothobranchius elucens was described by Béla Nagy in 2021, and assessed for the Red List by Nagy and Watters in the same year as Vulnerable based on its restricted geographic range. © Béla Nagy
Bagarius vegrandi © Nonn Panitvong.jpg
Bagarius vegrandis was described by Ng & Kottelat in 2021. An assessment of the species completed by Ng has been submitted to the IUCN Red List Unit for publication. © Nonn Panitvong

Shoal are keen to encourage researchers and taxonomists to conduct Red List assessments when they discover and describe new species. Can you offer any advice on how they can best do this?

I am also keen to encourage researchers and taxonomists to assess species for the IUCN Red List after describing them! I work with a handful of species experts that do this already, but would welcome if this practice became more widespread. Lots of the information that is provided as part of the description of a species is also relevant to a Red List assessment, for example the known distribution and habitats of the species. Additionally, those involved in the discovery and collection of a species are generally familiar with activities occurring in the distribution of the species that might be observed to (or can be inferred to based on knowledge of similar species) have negative effects on the species, therefore representing known or potential threats. Together, this provides a good basis for a Red List assessment.

Some taxonomic descriptions already contain sections on the conservation status of a species, but these don’t constitute an official Red List assessment – Red List assessments are only official once they have been through the full IUCN Red List assessment process and been published on the IUCN Red List website. This is to ensure that the IUCN Red List categories and criteria have been applied correctly and consistently. Although not always the case, many recently described species are assessed as either Data Deficient (DD) or threatened, given they are often relatively poorly known or occur in poorly known areas, and may be rare or have highly restricted distributions.

For any researchers interested to assess their newly described freshwater fish species for the Red List (or any species for which they have the relevant knowledge), I would advise that they contact me and I will be able to guide them through the Red List assessment process. Alternatively, there are lots of helpful resources available via the Red List website, including a free online Red List training course.

Paratrygon orinocensis

Paratrygon orinocensis was described by Loboda, Lasso, Rosa & Carvalho in 2021. The species is currently being assessed for the Red List by the IUCN SSC Shark Specialist Group. © LOBODA, LASSO, ROSA & DE CARVALHO

Describing new species: an interview with Ralf Britz

Ralf Britz collecting in Myanmar © Ralf Britz

Dr. Ralf Britz is a leading ichthyologist and taxonomist, and Head of the Ichthyology Section at Senckenberg World of Biodiversity. He has been involved in a total of 73 species descriptions and has been a key team member in the discovery of seven species which needed the creation of new genera. He was also the lead author on two papers describing the Gollum snakehead Aenigmachanna gollum: a new species in a new genus in an entirely new family.

With Shoal’s release of a landmark New Species 2021 report tomorrow, we caught up with Ralf to get the low-down on what discovering and describing new species really means.

What does it mean to describe a species, and how is it done?

When you describe a new species scientifically this process is often referred to among the public as having identified a new species. The process starts with the impression that you have found a species that does not have a scientific name, i.e. it is unknown scientifically. You then need to compare your specimens of what you think may be a new species with specimens of similar species that already have a name.

As taxonomy is one of the oldest scientific biological disciplines, this can be quite a cumbersome process, because you have to deal with all the species descriptions since and including Linnaeus’ 10th edition of his Systema naturae, published in 1758 and the starting point of animal taxonomy. If you are lucky and the group you work on has only a few species, then it is easy to compare your material with already collected material of the other species. This usually involves comparison with what we call type specimens, the specimens used to describe species. One of these type specimens is chosen as the holotype, the actual name bearer, the one specimen that is permanently linked to that name. These are stored ideally in publicly accessible museum collections. If, after comparison, you find that the specimens of what you thought were a new species are identical to one of the already described ones, then that is the end of the story. But if you find consistent and significant differences to all the known species in the group you are studying then you have probably found a new species.

The next step is then to write up a scientific manuscript in which you detail how your new species differs from already described (named) species, and you propose a name for it. The name may refer to a characteristic feature of the new species, or the place where it was collected, or it may honour a person, such as the person who collected it, an influential colleague or someone who supported your work.

In most cases the new name concerns just the new species. But sometimes you find an organism that you cannot easily fit into a larger group of similar and closely related species, a group we call a genus. In this case you may need to create a new genus for this new species. Here, the same rules apply you need to check all genera (plural of genus) in the larger group of organisms (a group we call a family). If you find you cannot fit it into one of the known genera, you can describe a new genus.

Once you have written up your findings relating to a new species or new genus, you submit your manuscript to a scientific journal for peer review. This means the manuscript is sent to other experts in the field who read your manuscript and point out potential problems, errors, mistakes etc. They provide the quality check before a manuscript is accepted and then published. They may ask you to revise your manuscript, check sources you may have overlooked, ask for additional details, or if you have made some major mistakes, suggest to reject your manuscript. If you have done your job, though, it may need no or just minor revision and will then get accepted for publication. Once it is published by a scientific journal and you have made sure you followed all the necessary steps that are required by the Code of Zoological Nomenclature – a set of rules that determine what has to be done for a name to be published in a valid way – then the new species is officially described and carries the name you have chosen.

I want to briefly touch on a worrying aspect of species descriptions that has started to plague taxonomy: the unholy alliance between self-proclaimed taxonomists and journals that will publish anything of any quality if you pay for it, the so-called predatory journals. There is an increasing number of manuscripts getting published which did not go through the strict and necessary step of peer review. Publication of these poor-quality species descriptions is a problem, because you cannot just ignore them as in other areas of science where poor papers just disappear in the garbage dump of scientific publications. Even poor-quality papers that describe new species will need to be considered due to the specific rules of nomenclature that need to be applied. Showing that these manuscripts are poor quality, and that the so-called new species is actually not new often involves so much more work, effort, time and money from you than the person invested who wrote the poor-quality manuscript. I know of cases in which one person described more than 20 new species from a well-known area of the world, all in predatory journals and with not a single of these so called new species really being new. Imagine that for each of these 20 or so new species you need to demonstrate that the original paper describing them is of poor quality and that these are not new species. This means you waste precious time, in which you could have described 20 new species with the level of quality that is necessary and is guaranteed by a proper peer review. Such taxonomic vandalism, as it has been termed, hampers the discovery of new species in a time when diversity is disappearing at an alarming rate.

Cyanogaster noctivaga
Cyanogaster noctivaga © Ralf Britz

Are there any species descriptions you’ve been involved with that you found particularly memorable or noteworthy?

Oh yes, absolutely. I have a soft spot for the weird and wonderful. I was involved in the description of Paedocypris progenetica, the smallest fish and vertebrate species. Then Danionella dracula, an equally tiny relative of D. cerebrum. But D. dracula has impressive large fangs. Then there was a new species and genus of earthworm eel from Myanmar, which I named after my daughter, Pillaiabrachia siniae. And during night collecting in the Rio Negro in the Amazon basin we found a new brilliantly blue coloured little fish, the blue bellied night wanderer, as we named it, Cyanogaster noctivaga. But the most memorable is Aenigmachanna gollum. When I first saw a photo shared on social media and sent to me by my colleague Rajeev Raghavan from Kochi, my heart stopped, as I had no idea what kind of fish I was looking at. Well, it ended up in a genus and family of its own.

Danionella dracula female © Ralf Britz
Danionella dracula female © Erwin Schraml
Pillaiabrachia siniae © Ralf Britz
Pillaiabrachia siniae © Ralf Britz

212 new freshwater fish species sounds like a lot in one year. What does this level of discovery tell us about the extent of what remains unknown in the planet’s freshwaters?

It sounds like a lot, but this has been the general trend of freshwater species discovery over the last few decades. There are still large parts of our planet that have not been explored and we keep discovering new animals that we had no idea existed. Finding a new species of an already established genus is exciting, but discovering entirely unknown lineages of higher taxonomic categories still today teaches us how much we do not know. And then keep in mind that only a tiny, tiny fraction of earth’s water volume, just around 0.03%, is freshwater in lakes and rivers and habitable for fishes. And yet, we have all this incredible diversity there. Mindboggling.

What is it about freshwater that leads to such incredible biodiversity?

I would say it is the more local situation and more diverse habitats that you get in freshwaters: you have river basins that are separated by land from other basins. There species evolve that are endemic to this river basin. Then you have ecological separations of river mouths from lowland parts of the rivers, separation of these from the more mountainous faster flowing parts of rivers and finally the rapidly flowing headwaters. This leads to endemism in different parts of the same river. These different parts of the same river will not only differ in the velocity of the water but also in the water temperature, amount of dissolved oxygen, pH, conductivity. Imagine that you have this basically in every major river.

Add this to the fact that through geological events over millions of years you have separations of parts of rivers and reunion of others, so there is a multitude of habitats changing over time and often very restricted endemisms.

All of these factors together act as species pumps that are obviously working much faster than in the oceans.

Ralf collecting in the Rio Negro © Ralf Britz
Ralf collecting in the Rio Negro © Manuela Marinho

Why is it important to discover and describe new species?

There are many different aspects to this question. One is this: if we consider the entire picture of lifeforms that evolution has produced on our planet, then we would miss many pieces of a complex puzzle if we stopped exploring. Think of the painting of Mona Lisa with hundreds of thousands of holes in it. You would not want to look at that.

Understanding diversity may also enable us to better understand how this diversity interacts. Something may seem insignificant but is sometimes of the greatest importance. Just think of invasive species, pests of crops, indicator species that help you evaluate the quality of a habitat and our environment. New species may become important in research: just think of the zebrafish discovered back in 1822 but also Danionella cerebrum only described last year. New species are pieces of the evolutionary puzzle we did not know existed and because of that we had no idea what they may have to offer.

Do you think it is important for people to care that new species are still being discovered and described? Why?

My experience is that people are generally excited when you tell them about new species discoveries. To imagine there is still so much out there that is unknown to us is a fascinating thought.

It is also more urgent than ever that we go out and discover, as the diversity is disappearing fast. Just think of the image of Mona Lisa with the hundreds of thousands of holes. Would

it not make you sad to know that these will never be filled as the species disappeared before we identified them?

What can we hope to learn from new species discoveries and descriptions?

The most important part we can learn is that there are so many fascinating organisms out there that we have not even discovered. Sometimes it is a new species that looks very much like one we already know, but often we discover a true gem, something unimaginable, unexpected, something we would have bet money does not exist. And these are special moments when you sit there quietly in awe of the evolutionary diversity our planet has produced.

Is there anything you would like to add?

Taxonomy, discovering, describing and understanding the evolutionary diversity that surrounds us to me is one of the most satisfying parts of my life. I would never trade it for anything else.

Danionella dracula scanning electron microscope image © Ralf Britz
Danionella dracula scanning electron microscope image © Ralf Britz