Tag Archives: Conservation

Study on the Cuban boa reveals deep genetic diversity

Some time ago, Ivan Rehák from the Zoo Prague informed us about a new genetic study on the Cuban boa Chilabothrus angulifer that he co-authored . We are very thankful for this and appreciate the study. We are deeply sorry for not covering it earlier.

The team of researchers addressed the question whether the Cuban boa is in fact a species complex. They analyzed the mitochondrial haplotype structure of the European ex situ population of Cuban boas. The results revealed a high degree of diversity. 96 specimens were sequenced and 25 distinct haplotypes detected.

The results further indicated a deep divergence among three principal haplogroups, with bayesian estimates of the divergence time equal to 3.57 and 2.26 Mya respectively.

Rehák and colleagues consider this divergence as an argument for diverse evolutionary lines whose distance corresponds to or is greater than among some other – taxonomically recognized – species of the genus.

Whether these lines represent whole species or subspecies needs to be tested by further in depth studies with genetic material collected from different locations in cuba.

To read the study please click here

 

Citations

EAZA Reptile TAG attendance

The European Association of Zoos and Aquariums (EAZA) is one of the leading Zoo Associations of the world. According to it’s website, EAZA’s mission is to facilitate cooperation within the European zoo and aquarium community towards the goals of education, research and conservation.

We were invited by Michel Ansermet (Director of the Aquatis Lausanne, Switzerland) and Guido Westhoff (Head Curator, Tierpark Hagenbeck, Hamburg, Germany), to give a short talk about our conservation initiative during the EAZA Reptile & Amphibian TAG meeting (held from March 7th to March 11th). This meeting was a great honor to take part in and it was amazing to hear about zoo reptile keeping successes as well as the challenges the professional community faces.

It was especially interesting to see so many research and conservation projects – many of them very successful – performed in various reptile species. From the the implementation of IUCN’s “One Plan Approach” in South East Asia to protect turtles to the assisted reproduction of Orlitia borneensis in the Gdansk Zoo. From Investigating movement, distribution, abundance and diet of the Salt Water crocodile in Australia to the Orinoco crocodile repatriation in Venezuela. From novel insights of wild living Varanus salvadorii to a conservation initiative, The Kimboza Forest Gecko Project.  Each of the the talks was highly interesting, scientifically sound and very well crafted.

We had the great honor to give the first talk on the snake session (day four). Our talk was entitled: Before it’s too late – a conservation initiative for West Indian boas. Our aim was/is to encourage zoos to take some species of West Indian boas into their programs, since the West Indies are underrepresented in zoological reptile collections.

After the talk we received very positive feedback and were happy to have made some new contacts.  However, none of the institutions present at the meeting vocalized a will to open their collection to West Indian boa herpetofauna. Our collaboration initiative is still open and we welcome any scientifically led zoo to collaborate with us on a non-commercial basis. We hope that conservation initiatives will realize that the conservation of one of the top biodiversity hotspots of the world deserves more attention than it currently receives.

The problem at this point is resource partitioning in zoos. Conservation is currently in need of many helping hands and funds, while zoos have only a limited amount of space and resources. These must be used wisely to have the biggest possible impact. To put it into perspective though, out of 6 studbooks for snakes, two exist for West Indian boa species: Chilabothrus angulifer  (EAZA) and Chilabothrus subflavus (AZA). While we are happy about this in general, we remark that both species are much less threatened than many of the Hispaniolan Chilabothrus taxa. Chilabothrus subflavus is bred in increasing numbers in the US and Europe by private breeders and zoos alike. We would very much like to see an increase in the number of species on display in Public and Private zoos.

Here is our shout out: Every zoo that displays a Burmese python or a Green Anaconda, think about replacing it with several West Indian boa species. Every corn snake can be replaced by a small West Indian boa, every Boa constrictor can be replaced by a Boa orophias or B. nebulosa, etc. This would have a tremendous impact on the visibility of this fragile ecosystem, which it sorely needs.

Citations

 

Breeding the endangered Jamaican Boa, Chilabothrus subflavus

Jamaican Boas have been bred as a measure of conservation since the 1970s.  Today the species is still listed as Vulnerable (VU) by IUCN and listed in Appendix I of the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES).  The species is currently kept by multiple zoos and aquaria as well as private breeders.  We sum up the annual breedings of this boa that we are aware of.  Westindianboas.org provided over the years several breeders with breeding stock animals in the US.  Unfortunately, restrictions make the export of this species unnecessarily difficult.  Considering the good breeding successes on both sides of the Atlantic, it should be in the interest of conservation to exchange genetic material and thus continue to maintain a diverse genetic foundation for conservation.

Several litters of the Jamaican Boa, Chilabothrus subflavus, were born this season in the US, the UK and the EU.  This particular litter, shown below, was born 9 September, 2021.  Produced by Rob Stone of the US, the litter numbered 17 live with no stillborn or unfertilized ovum.  Neonate weights ranged from 10.83 g to 13.93 g, with a mean of 12.98 g.  SVL of the neonates was 25.72 cm to 33.18 cm, with a mean of 30.13 cm.

Sire of the litter. Photo Rob Stone
Dam of the litter. Photo Rob Stone
Sea of subflavus. Photo Rob Stone

The Jamaican Boa is highly variable in color and pattern; the ontogenetic color change will take 18 – 24 months to complete.
The following litters were also produced during the 2021 season:

  • UK:  12 live, 2 stillborn and 7 unfertilized ova on 3 October, 2021.  Bred by Tom Middlebrook and Faye Da Costa.
  • US:  15 live, 1 unfertilized ovum on 27 September, 2021.  Bred by David Muth and Jared Rager.
  • US:  34 live, 3 stillborn and 3 or 4 unfertilized ova on 26 September, 2021.  Bred by Tom Crutchfield.
  • Germany:  9 live, 1 stillborn and 6 unfertilized ova on 14 September, 2021.  Bred by Sebastian Hölch.
UK litter of 12. Photo Tom Middlebrook and Faye Da Costa

Visit the chapter for the Jamaican Boa here for more in depth information and photos.

Chilabothrus neonate season continues with Bahamas Boas

The Bahamas Boa Chilabothrus s. strigilatus is a species that relatively few private persons keep and, to our knowledge, no zoo worldwide has these fascinating boas on display.  We are more than pleased to announce that a litter of C. strigilatus was  born on October 1st in Germany.

Chilabothrus strigilatus babies with snake mother

Birth began in the morning hours from 8.30am.  The moon phase was in between half and new moon.  The pressure system was high and the morning was sunny, however, in the evening a low pressure system came in and it started to rain.

The post ovulation shed of the female boa occurred on June 13th, thus 110 days passed between post ovulation shed and birth.  Noticeably, the yolk was entirely used up in all babies and only the allantois was present as extraembryonic tissue.

Chilabothrus strigilatus babies the first sight

The litter contained 27 perfectly healthy babies. weighing between 12 and 16 grams.  Average weight was 14.07 grams.  The length of the babies is around 43 cm.  The litter did not contain any unfertilized eggs, deformed or stillborn babies.

Chilabothrus strigilatus babies with mother

The relative clutch mass (RCM) indicates the amount of mass spent on the babies by their mother.  The babies had a combined birth weight of 380 grams and the mother weighed post parturition 1087g.  The RCM is calculated as: baby mass / (baby mass + mother mass post parturition).  The mother spent 25.9% of her mass in babies, not accounting for fluids and extraembryonic tissue which could not be accurately weighed.

Chilabothrus strigilatus babies
Chilabothrus strigilatus baby on hand

More information on the species can be found here.

Corallus cookii; documenting its life cycle in captivity

A small litter of Corallus cookii, born September 26 at approximately 10:00 p.m., consisted of six live neonates, three small unfertilized ovum and no stillborn.  The neonates weighed 5.51 g to 14.09 g with an average weight of 11.86 g.  The female moved away from the heat source immediately after shedding on 16 September.  She also dropped a large quantity of pre-birth material in the bowel movement.

Litter of six C. cookii born September 26, 2021.

There is a variety of pattern and color between the neonates, though this polymorphism is not as pronounced as it is with C. hortunalus or C. grenadensis.

The iconic rhomboids found on C. cookii.

The female  boa, once finished with parturition,  consumed all three unfertilized ovum-possibly the first time this behavior has been documented in the species.

A total of three litters was produced in 2021:

  • US:  6 live and 3 unfertilized ovum on 26 September.  Smallest neonate weighed 5.51 g and the largest weighed 14 g with an average weight of 11.86 g.
  • US:  5 live, 1 stillborn and 6 unfertilized ovum on 8 October.  Smallest neonate weighed 7.96 g and the largest weighed 9.89 g with an average weight of 8.65 g.
  • US:  5 live, 1 stillborn and 2 unfertilized ovum on 8 October.  Smallest neonate weighed 7.4 g and the largest weighed 12.0 g with an average of 10.18 g.

For more photos and a complete overview of the species, view the C. cookii chapter.

 

Climate Change and the importance of captive breeding for species survival

Humans as a species behave in interesting ways.  We respond to events such as a terrorist attack, a flooding or a wildfire with some sort of intellectual answer – not always the right response but that’s a different story.  On the other hand, dramatic events that affect our world as a whole and which are long lasting seem too big to fathom.
One such event is the ocean circulation of the Atlantic Ocean, which includes the Gulf Stream, has probably lost stability over the past century and could now be facing a crucial tipping point.  The news should have sent shockwaves through the world – but it didn’t.
Niklas Boers, a climate researcher of the Potsdam Institute for Climate Impact Research (PIK) came to conclude this.  He published his findings in the Journal,  Nature Climate Change .

https://upload.wikimedia.org/wikipedia/commons/9/97/Hurricane_Maria_2017-09-19_1742Z_%28gallery%29.jpg
Hurricane Maria to the southeast of Puerto Rico. Source Wikimedia Commons
Why is this important and what does it mean?

The Gulf Stream is considered the long-distance heater of Europe, as it brings heat as far as the British Isles and off the coast of Norway.  The Gulf Stream, in turn, is part of the larger Atlantic Meridional Overturning Circulation (AMOC).  This carries warm and salty water northward at the ocean surface, while cold and low-salinity water flows back at depth.  Based on evidence from Earth’s history, researchers suspect that the circulatory system can, in principle, switch between two different operating states: a strong circular motion, as currently observed, and a much weaker one.
Because the AMOC system redistributes large amounts of heat, it affects weather worldwide. A sudden change from the strong to the weak state would therefore have serious consequences: Europe would possibly cool, while hurricanes would increase over the Atlantic.
A number of factors are probably responsible for the approach to the tipping point.  The increased input of freshwater originating from the melting of the Greenland ice masses is a main factor while, in addition, precipitation and input from rivers into the ocean have also increased as a result of climate change.  Fresh water is lighter than salt water and therefore tends to remain at the surface instead of sinking into the depths.  This process is slowing down the normal ocean circulation.
Boers traced the telltale signs of change in ocean circulation, such as saltwater content and ocean temperature, back over 150 years.  His analysis shows that the AMOC system transitioned from relatively stable conditions to a point near a critical threshold over the last century.

And the boas?

We saw in the recent past glimpses of what hurricane intensification means for the West Indies. Hurricane Maria devastated the northeastern West Indies in September 2017, particularly Dominica (Category 5), Saint Croix, US Virgin Islands and Puerto Rico (Category 4) were affected. It is regarded as the worst natural disaster in recorded history to affect those islands. Considering the above mentioned study, we need to prepare for more of this.
But even if some islands are unaffected by hurricanes, and aside from big tangible impacts, even a small change in weather, which might not be considered as dramatic in human terms, might have a huge impact on the boas. The food source of the boas might be affected and most probably the ability to reproduce will be strongly affected, since reproductive stimuli to which the boas evolved are altered and the chances of proper thermoregulation for gravid females might decline.
We have but one chance to improve the likelihood of survival for the West Indian Boas – captive breeding through willing institutions and the Invisible Ark.

Addendum

On August 9th the IPCC published it’s Sixth Assessment Report .

Key findings:

  • Global surface temperature was 1.09C higher in the last decade (2011-2020) than in the last pre industrialisation half century (1850-1900).
  • The past five years have been the hottest on record since 1850
  • The recent rate of sea level rise has nearly tripled compared with 1901-1971
  • Human influence is “very likely” (90%) the main driver of the global retreat of glaciers since the 1990s and the decrease in Arctic sea-ice
  • It is virtually certain that hot extremes including heatwaves have become more frequent and more intense since the 1950s, while cold events have become less frequent and less severe

https://www.ipcc.ch/assessment-report/ar6/

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Chilabothrus neononate season begins with Ford’s Boa

This time of the year is the start of the season when West Indian Boa babies are born.  The various species employ slightly different reproductive strategies, reflected in their annual timings of birth.  Ford’s Boa (Chilabothrus fordii) is generally the first of the genus to give birth in- and ex situ.
This litter of four C. fordii, produced by a five year old female, was born on July 24, 2021 in Germany. The moon phase was full moon, a low pressure system was in the making and the boas were born in the hours of the (not so early) morning and discovered around 11am – most likely – soon after birth.  Yolk sacs and fetal membranes were still attached.
The weight of the boas was determined with a household fine scale. The measurements of the seemingly largest specimen was approximately 25 cm and weighed 4.9 grams. The shortest was about 23 cm and weighed 4.4 grams.  The weights of the others were 4.5 grams and 4.8 grams, respectively.  Mean neonate weight was 4.65 grams.
No stillborn, deformed young or unfertilized eggs were discovered.  It appears unlikely that the female produced and consumed them because:  (a) the boas were discovered right after birth and ( b) no signs of consumption were made – the mother looked very emaciated.
The boas are from Jeff Murray, a mixture of US lines.  Jeff coined the phrase: It’s Christmas in July!  Which appears very accurate when one sees these beauties.

A litter of Chilabothrus fordii with the mother boa. Photo by E. Fitzpatrick
A litter of Chilabothrus fordii. Photo by E. Fitzpatrick

Litter of 9 neonate C. fordii born 27 July. Photo Jeff Murray

The first newborn boa shed after 5 days. A comparison of the first skin to an adult C. fordii shed illustrates the size differences.  Notice that the skin stretches when the boas shed, the baby boa measures about 25 cm, whereas the skin measures close to 40 cm. The adult boa skin has stretched to a lesser percentage.

Size comparison between adult shed skin and newborn first shed.

We look forward to more litters coming on both sides of the Atlantic.  To read more about the fascinating Ford’s Boa, click here