Presented by Charles & Linda Raabe
Mactan Island, The Philippines
© 2009 All Rights Reserved
The infraorder Caridea is the largest shrimp group in the world, containing almost 2,800 described species with estimates of twice that number of species yet to be discovered and described. Although they occur in all of the world's oceans, the Caridean shrimp reach their highest level of species and generic diversification in the Indo-Pacific. Within this region, they are only rivaled in their species diversity by the Alpheidae, earning them a place within this online resource as well.
In the tropical marine environment many small species have evolved specialized lifestyles, living commensally on and within various species of sponges, corals, echinoderms and polychaetes, while others lead a more free-ranging lifestyle. These various lifestyles are what I find the most interesting and hope to continue my study of these relationships. Coloration :
Since it is my goal to examine and present the live colorations of the shrimp that I am able to collect in addition to their morphology, it is important to try and understand why the various species develop coloration or not and that there can be great variation of colors and patterns within a species.
The exoskeleton of many carideans are completely transparent, especially with juveniles or very small species yet there are species that are very colorful as shown in the example. These colors are derived from pigments that are either located within the exoskeleton or within cells below the exoskeleton. Without such pigmentation the carideans would appear transparent except for the black of their eyes, opaque internal organs and food filled stomachs and digestive tracts, of which can give the shrimp a green coloration due to the visible green algae that they have consumed.
In areas of the shrimp that are transparent, such as the mouthparts, appendages and tail fans, they may appear a light amber coloration. These golden hues are due to a hardening of the exoskeleton's outer layers known as sclerotization, a chemical process also known as quinone tanning. This hardening of the outer layers protects the
exoskeleton from wear and tear while giving the shrimp a bit of color, although this type of coloration can not be used for identification purposes as all shrimp are subject to sclerotization in one degree or another.
Live coloration becomes important as the preserved specimens of many closely related species are so similar in their morphological traits that species cannot be distinguished. Color patterns exhibited in life often clearly show species differences that the morphology of preserved specimens cannot.
A very important caveat in coloration and patterns of coloration is that variations of those colors do not always mean that there are distinct, separate species (Bauer 2004)
. Color variations can also be environmentally determined by background. A good case in point is Periclimenes commensalis
, a commensal of Crinoids that themselves have varied colorations which the shrimp are able to mimic exactly, meaning that a single species can appear in any number of colors yet tend to follow the same species patterns of coloration. On a single crinoid I found two P. commensalis
showing this ability, both having a black background coloration yet showed a variation in the yellow coloration of their pattern. One being an orange pattern and the other a yellow.
Obviously if color morphs alone were recognized as individual species then the understanding of their ecology, behavior and evolution would be very confused. But if color patterns vary among morphologically similar individuals living in the same geographic area and have consistent differences in other traits such as behavior, preferred habitat and mate choice, then that could be an indication of different species. Of course such close similaritys would always cast doubt upon their actually being different species yet with todays ability to test DNA differences, such doubts can now be much more easily confirmed or ruled out regarding a species status.
The superfamily Palaemonoidea are of greater interest to me as they make themselves easily visible or at the least, easily found, which is evident by the species I have collected and photographed below. This single superfamily has enough members that one could spend a life time learning of their many morphological differences, meaning that I will most likely be quite busy and intrigued for many years to come. I expect in due time to add many more family groups within this superfamily as collecting luck will have it.
It is our goal to provide the best possible photographic identification features with emphasis on live colorations while providing enough taxonomy details to be of an aide in identifying other specimens. Photographic quality is of course fully dependent on not only my available equipment, but my skills with said equipment and my ability to obtain specific details through dissection, which should improve as I gain experience and of course, patience.
PLEASE NOTE :
When I have but a single specimen to work with the amount of and quality of photographic details will most likely suffer as I intend to keep single specimens intact as much as possible in case the specimen is needed for examination by others much more qualified to do so. Acknowledgments :
A special Thank you goes out to :Dr. A.J. Bruce
of the Queensland Museum, AustraliaDr. Ivan N. Marin
of the A.N. Severtzov Institute of Ecology and Evolution, Moscow, RussiaDr. A. Anker
and Leslie Harris
of the Los Angeles Natural History Museum for their kind assistance with identifications. Their time and efforts are greatly appreciated.
( CAR 024 ) Unknowns -
For you Shrimp Experts, Please help identify the following specimens or add to the text content, all suggestions are greatly appreciated.
Recently Collected specimens - Any newly found specimens will be placed in this area until they are identified.
Those species which have been examined and have yet to be positively identified, most of which have but a single collected specimen and are awaiting further specimens to be collected in order to verify their identificaton.
Classification : Kingdom
: Animalia Phylum
: Arthropoda Subphylum
: Crustacea Class
: Malacostraca Order
: Decapoda Suborder :
: Caridea Superfamilies
: Alpheoidea - Atyoidea - Bresilioidea - Campylonotoidea - Caridea Incertae Sedis - Crangonoidea - Nematocarcinoidea - Oplophoroidea - Palaemonoidea - Pandaloidea - Pasiphaeoidea -
Procaridoidea - Processoidea - StylodactyloideaSuper Family - Alpheoidea
Family Groups - Alpheidae - Barbouriidae - Hippolytidae - Ogyrididae Family - Alpheidae Rafinesque, 1815 Genus Groups
- Alpheopsis - Alpheus - Amphibetaeus - Arete - Aretopsis - Athanas - Athanopsis - Automate - Betaeopsis - Betaeus - Deioneus - Fenneralpheus - Leptalpheus - Metalpheus - Neoalpheopsis - Parabetaeus - Potamalpheops - Racilius - Salmoneus - Salomeus - Synalpheus - ThunorReference(s): Genus - Alpheus Fabricius, 1798 Species - A. aculeipes - A. acutocarinatus - A. acutofemoratus - A. affinis - A. albatrossae - A. albatrossi - A. alcyone - A. alcyone de - A. amblyonix - A. amblyonyx - A. amirantei - A. amirantei sizou - A. angulosus - A. angustodigitus - A. architectus - A. arethusa - A. armatus - A. armillatus - A. astrinx - A. audouini - A. australiensis - A. australosulcatus - A. avarus - For the complete listing, click HERE
Athanas spp. (CAR025) Genus - Synalpheus Bate, 1888 Species
- S. acanthitelsonis - S. agelas - S. albatrossi - S. anasimus - S. ancistrorhynchus - S. apioceros - S. bannerorum - S. bispinosus - S. bituberculatus - S. biunguiculatus - S. bousfieldi - S. brevicarpus - S. brevifrons - S. brooksi - S. carinatus - S. charon - S. comatularum - S. coutierei - S. coutierei, - S. crosnieri - S. demani - S. digueti - S. disparodigitus - S. dominicensis - S. dorae - S. echinus - S. filidigitus - S. fossor - S. fritzmuelleri - S. gambarelloides - S. gamberelloides - S. goodei - S. gracilirostris - S. grampusi - S. gravieri - S. harpagatrus - S. hastilicrassus - S. heardi - S. hemphilli - S. heroni - S. herricki - S. iocasta - S. laevimanus - S. laticeps - S. lockingtoni - S. longicarpus - S. macclendoni - S. macromanus - S. minus - S. modestus - S. mulegensis - S. neptunus - S. neptunus germanus - S. neptunus neptunus - S. nobilii - S. occidentalis - S. odontophorus - S. pachymeris - S. pandionis - S. paraneomeris - S. paraneptunus - S. pectiniger - S. pescadorensis - S. pococki - S. quadriarticulatus - S. quinquedens - S. rathbunae - S. readi - S. redatocarpus - S. sanctithomae - S. scaphoceris - S. sciro - S. spinifrons - S. stimpsoni - S. stimpsonii - S. streptodactylus - S. tanneri - S. thai - S. theano - S. tijou - S. townsendi - S. tropidodactylus - S. tumidomanus
Hippolyte #1 (CAR 033) Hippolyte #2 (CAR 039) Hippolyte cf. commensalis (CAR 032)
Genus - Latreutes Stimpson, 1860 Species
- L. acicularis - L. anoplonyx - L. compressus - L. ensifer - L. ensiferus - L. fucorum - L. inermis - L. laminirostris - L. mucronatus - L. parvulus - L. planirostris - L. porcinus - L. pygmaeus - L. pymoeus
Genus - Saron Thallwitz, 1888
Species - S. marmonratus - S. neglectu
Genus - Thor De Man, 1888
Species - T. amboinensis - T. dobkini - T. floridanus - T. manningqi - T. paschalis - T. spinosus
T. amboinensis (CAR 012)
Super Family - Palaemonoidea Rafinesque, 1815 Family Groups -
Anchistioididae - Desmocarididae - Euryrhynchidae - Gnathophyllidae - Hymenoceridae - Kakaducarididae - Palaemonidae - Typhlocarididae Family - Gnathophyllidae Guérin-Méneville, F.É. 1856 Genus Groups - Gnathophylloides - Gnathophyllum - Hymenocera - Levicaris
G. americanum (CAR044)
Family - Palaemonidae Rafinesque, 1815 Genus groups - Calathaemon - Climeniperaeus - Cryphiops
SubFamilies - Palaemoninae Rafinesque, 1815 Genus Groups
- Brachycarpus - Exopalaemon - Leander - Leandrites - Leptocarpus - Macrobrachium - Nematopalaemon - Palaemon - Palaemonetes - Urocaridella - Pontoniinae Kingsley, 1878 Genus Groups
- Allopontia - Altopontonia - Amphipontonia - Anapontonia - Anchistus - Apopontonia - Araiopontonia - Balssia - Carinopontonia - Chacella - Chernocaris - Conchodytes - Coralliocaris - Coutierea - Crinotonia - Ctenopontonia - Cuapetes - Dasella - Dasycaris - Diapontonia - Epipontonia - Eupontonia - Exopontonia - Fennera - Hamiger - Hamodactyloides - Hamodactylus - Hamopontonia - Harpiliopsis - Ischnopontonia - Isopontonia - Jocaste - Laomenes - Lipkebe - Manipontonia - Mesopotonia - Metapotonia - Miopotonia - Neoanchistus - Neopontonides - Notopontonia - Onycocaridella - Onycocaridites - Onycocaris - Orthopontonia - Palaemonella - Paraclimenaeus - Paranchistus - Parapontonia - Paratypton - Periclimenaeus - Periclimenella - Periclimenes - Pericliminoides - Philarius - Platycaris - Platypontonia - Plesiopontonia - Pliopontonia - Pontonia - Pontonides - Pontoniopsis - Propontonia - Pseudocoutierea - Pseudopontonides - Rapipontonia - Sandimenes - Stegopontonia - Tectopontonia - Thaumastocaris - Tuleariocaris - Typton - Veleronia - Veleroniopsis - Vir - Waldola - Yeminicaris - Zenopontonia Genus - Conchodytes Peters, 1852
Species - C. kempi - C. maculatus - C. meleagrinae - C. monodactylus - C. nipponensis - C. tridacnae
C. meleagrinae ( CAR 016 )
Genus - Coralliocaris Stimpson, 1860
Species - C. brevirostris - C. graminea - C. macropthalma - C. nudirostris - C. pavonae - C. superba - C. taiwanensis - C. venusta - C. viridis Genus - Crinotonia Marin, 2006*
* "Differs from other pontoniine genera in the combination of several morphological features, including the absence of a podobranch on the second maxilliped, an arthrobranch on the third maxilliped; the presence of several robust disto-lateral and ventro-mesial teeth on the first segment of the antennular peduncle; the extreme dimorphism of the second pereiopods; third pereiopod with propodus having a serrated ventral margin, without distoventral spines, with a specialized dactylus. Crinotonia
is similar to the genus Pontoniopsis
which is also associated with Crinoid hosts." Species - C. anastasiae - C. attenuatus*Reference
: Dr. Ivan Marin (2006), Description of Crinotonia anastasiae
, New genus, New species, A new crinoid associated Pontoniine shrimp from Nha Trang Bay, Vietnam. The Raffles Bulletin of Zoology 2006 54(2): 321-340.
Genus - Cuapetes Okuno, 2009 * Species:
Currently, this genus consists of the following 24 species all previously assigned to Kemponia
(see Bruce 2004; Li 2008) in addition to the type species, Cuapetes nilandensis (Borradaile, 1915)
- Cuapetes agag (Kemp, 1922)
-Cuapetes akiensis (Kubo, 1936)
- Cuapetes americanus (Kingsley, 1878)
- Cuapetes amymone (De Man, 1902)
- Cuapetes anacanthus (Bruce, 1989)
- Cuapetes andamanensis (Kemp, 1922)
- Cuapetes calmani (Tattersall, 1921)
- Cuapetes darwiniensis(Bruce, 1987)
- Cuapetes demani (Kemp, 1915)
- Cuapetes edwardsi (Paulson, 1875)
- Cuapetes elegans (Paulson, 1875)
- Cuapetes ensifrons (Dana, 1852)
- Cuapetes grandis (Stimpson, 1860)
- Cuapetes johnsoni (Bruce, 1987)
- Cuapetes kororensis (Bruce, 1977)
- Cuapetes lacertae (Bruce, 1992)
- Cuapetes longirostris (Borradaile, 1915)
- Cuapetes paulsoni (Bruce, 2003)
- Cuapetes platycheles (Holthuis, 1952)
- Cuapetes rapanui (Fransen, 1987)
- Cuapetes seychellensis (Borradaile, 1915)
- Cuapetes suvadivensis (Borradaile, 1915)
- Cuapetes tenuipes (Borradaile, 1898)
- Cuapetes ungujaensis (Bruce, 1969)
: Junji Okuno - Cuapetes Clark, 1919, a senior synonym of Kemponia
Bruce, 2004. Zootaxa 2028: 67–68 2009 C. lacertae (Kemp001) C. kororensis (Kemp003) C. amymone (Kemp004) C. cf. elegans (Kemp 005)
Genus - Exoclimenella Bruce, 1994
Species - E. denticulatus - E. maldivensis - E. sibogae
Genus - Hamodactylus, Holthuis 1952
Species - H. aqabai - H. boschmai - H. noumeae
Genus - Hamopontonia Bruce, 1970
Species - H. corallicola - H. essingtoni
Genus - Harpiliopsis Borradaile, 1917
Species - H. beaupresii - H. depressa - H. spinigera
Genus - Harpilius Dana, 1852
* "The genus Harpilius
appears particularly closely related to two other pontoniine genera that are also obligatory scleractinian associates, Vir
. Their general morphologies are very similar, and all have a well developed finger-like medial process on the fourth thoratic sternite. All species of these genera have simple hamate ambulatory dactyls."
Species: H. bayeri - H. consobrinus - H. lutescens * Reference:
A.J. Bruce (2004). A partial revision of the genus Periclimenes
Costa, 1884. Zootaxa 582: 1-26.
Genus - Jocaste Holthuis, 1952 Species
- J. japonica - J. lucina - J. platysoma Genus - Palaemonella Dana, 1852 Species
- P. atlantica - P. crosnieri - P. elegans - P. lata - P. maziwi - P. pottsi - P. pusillus - P. rotumana - P. spinulata - P. tenuipes
Genus - Periclimenaeus Borradaile, 1915
Species - P. arabicus - P. ardeae - P. arthrodactylus - P. ascidiarum - P. atlanticus - P. bermudensis - P. bidentatus - P. bouvieri - P. bredini - P. caraibicus - P. chacei - P. crassipes - P. diplosomatis - P. djiboutensis - P. garthi - P. gorgonidarum - P. hancocki - P. hebedactylus - P. hecate - P. holthuisi - P. jeancharcoti - P. leptodactylus - P. lobiferus - P. manihinei - P. maxillulidens - P. minutus - P. nobilii - P. orbitospinatus - P. orontes - P. pachydentatus - P. pacificus - P. palauensis - P. pearsei - P. perlatus - P. quadridentatus - P. rastrifer - P. rhodope - P. robustus - P. schmitti - P. spinicauda - P. spinimanus - P. spinosus - P. spongicola - P. storchi - P. stylirostris - P. tchesunovi - P. tridentatus - P. trispinosus - P. truncatus - P. tuamotae - P. uropodialis - P. usitatuswilsoni - P. zanzibaricus - P. zarenkovi
Genus - Periclimenella Bruce, 1994
Species - P. petitthouarsii - P. spinifera
P. spinifera (Peric001) Genus - Periclimenes Costa, 1844 Species: P.adularans - P.aegylios - P.aesopius - P.affinis - P.albatrossae - P.alcocki - P.aleator - P.amethysteus - P.andamanenesis - P. andresi - P.anthophilus - P.antonbruuni - P.batei - P.bowmani - P.brevicarpalis - P.brevicarpalus - P.brevinaris - P.brevirostris - P.brocketti - P.brockii - P.brucei - P.calcaratus - P.calcartus - P.carinidactylus - P.colemani - For the complete listing, Click HERE
R. galene (Rapi001) Genus - Sandimenes Li, 2009 Species
- S. hirsutus
Genus - Thaumastocaris Kemp, 1922
Species - T. streptopus
T. streptopus (CAR 040) Genus - Vir Holthuis, 1952
* " The genus Vir
was erected for Palaemonella orientalis
. Since then four species have been described and existence of further undescribed species has been mentioned. The two most recently described species, V. euphyllius
and V. pareuphyllius
were found in Nha Trang Bay, southern Vietnam, in association with hammer corals of the genus Euphyllia
. These two species appeared to be morphologically very similar, differing mainly in the shape of the rostrum, different configuration of lobes on the distal margin of the carpus of the second pereiopods, and the size of the mandibular palp." Species
: V. philippinensis - V. colemani - V. euphyllia - V. pareuphyllius
* Reference material - Vir euphyllia.pdf
Super Family - Pandaloidea Haworth, 1825
Family Group - Pandalidae Haworth, 1825
Genus Groups - Atlantopandalus - Chlorotocus - Dichelopandalus - Heterocarpoides - Heterocarpus - Pandalidae - Pandalina - Pandalopsis - Pandalus - Pantomus - Parapandalus - Plesionika - StylopandalusReference(s):
Genus - Chlorotocus Costa, 1871
Species - C. jactans
Infraorder - Stenopodidea Claus, 1872 Family
- Stenopodidae Claus, 1872 Genus Groups - Engystenopus - Microprosthema - Odontozona - Richardina - Spongicoloides - Stenopus
Genus - Microprosthema Stimpson, 1860
Species - M. emmiltum - M. granatense - M. jareckii - M. plumicorne - M. semilaeve
M. plumicorne (micro001)
Symbiosis (Greek words meaning "living together") Is applied to any association which there is prolonged close contact between individuals of two species. The symbiont is the species that has abandoned its free-living habits to live with another, usually larger species that is termed the host. Different forms of symbiosis are defined by the costs and benefits (if any) to both species as explained in the following terms.
Amensalism = two organisms living together with no specific benefit to either. The relationship is neutral. Generally, something like a duck living next to a cat-tail or other wet land plant would fit here. The two organisms live together due to random events; any specific benefits to either party are so small as to be inconsequential.
Commensalism = two organisms living together, with one benefiting, the other is neutral.
Mutualism = two organisms living together, with both benefiting for the mutual good. Zooxanthellae (algae) in corals is a good example.
Parasitism = two organisms living together, one benefits, the other suffers, but it is non-lethal.Coral Symbionts
In the Indo-Pacific, the scleractinian (reef-building) corals appear to be very important hosts for symbiotic shrimps, providing cover in which the shrimp can hide along with the coral's stinging tentacles providing protection from predators and therefore are at the least, commensal. However, many shrimp symbionts have given up the free-ranging life style and remain at all times within the protection of the coral and feed either directly on the coral's mucus or take food particles that the coral has captured making the shrimp a parasite of sorts, although the coral most likely suffers very little due to the shrimp's feeding habits and it may be a good trade off for the coral as the shrimp also performs some service to the coral in the way of clearing sediments and possibly warding off coral parasites such as some nudibranch and copepod species. Echinoderm Symbionts
Quite a number of shrimp species take advantage of Echinoderm's defensive protection and gain not only the same protection from predators as the Echinoderm does, but also benefits from being on or within a mobile invertebrate that allows the shrimp to gather food as it either moves along the substrates or the shrimp simply steals food particles that the Echinoderm has collected.
Food for symbiotic shrimp may be as important as shelter in explaining their association with Echinoderms. Not only do the shrimp take advantage of passing or collected food particles they also have a ready food supply in the way of superficial tissues and associated mucus covering calcareious plates and spines of the Echinoderm host.
Species of the family Gnathophyllidae are often associated with Echinoderms although are considered free living but are often found near or on sea urchins or other Echinoderms. Those Gnathophyllum species not permanently associated with their possible hosts are most likely micropredators rather than symbionts tending towards parasitism. Anemone Symbionts
As with other shrimp genera utilizing various hosts as described above, there are a number of species that use anemone as their home. Some live at the base of the anemone while others are a bit more bold and stay within the stinging tentacles of the anemone, gaining protection from fish predators as most fish will not brave being stung by the anemone. As with other relationships, these shrimp may also benefit by feeding on the anemone's mucus and regurgitated undigested food. If the shrimp receives protection and food from the anemone, it is a commensal, but most likely leans towards parasitism.
It is doubtfull that the anemone recieves significant benefit from the shrimp although the nitrogenous excretions of the shrimp can slightly increase the abundance of zooxanthellae in the tissue of its anemone host. If the shrimp's fertilization of the zooxanthellae significantly boosts the zooxanthellae's energy contribution to the host, then the symbiosis between the shrimp and the anemone is mutualistic.Sponge Symbionts
Sponges have a variety of canals and spaces used to carry oxygenated water and suspended particles that serve as food for the sponge. They also produce some very noxious compounds that repel predators and thus make for a safe and convienent home for a number of shrimp species. However, little is known about the true relationship of these species to their sponge hosts. Studies by Duffy have however revealed quite a bit about the basic biology and evolution of sponge associates of the genus Synalpheus, several of which are obligate associates of sponges with some of them feeding directly on the sponge's tissue, making the relationship more parasitic than commensal. Duffy has also shown how the combination of symbiotic living on different hosts and abbreviated-direct development has led to much speciation in this genus. Eusocialty, which is known in only a few animal groups has evolved in some Synalpheus symbionts of sponges.
Mantle cavities of molluscs, especially the bivalves such as clams and oysters make for a good habitat for symbiotic shrimp. The cavities, which houses the gills of the mullusc, not only function in respiration but also in food collection of filter-feeding bivalves.
While providing obvious protection to the shrimp, the shrimp are also provided food in the form of mucus and/or food particles filtered out of the water by the gills of the bivalve. Species of the Pontoniine genera Conchodytes, Anchistus, Paranchistus and Platypontonia along with others, occupy this niche.
The above relationships are but a small sampling as there are a great many more such relationships. I have come to learn that regardless of where I look, there is bound to be a shrimp taking advantage of both shelter and food sources. Be it within clams, tunicates and sponges to living on the surfaces of gorgonians and anemone along with many free-ranging species it is of no surprise that if one stops and looks closely, anywhere, the odds are in favor of you finding a shrimp. References:Bauer, Raymond T. Remarkable shrimps : adaptations and natural history of the Carideans. University of Oklahoma Press, Norman, Publishing 2004Bruce, A.J. 1975. Coral reef shrimps and their colour patterns. Endeavour 34: 23-27Chace, F.A. Bruce A.J. The Caridean Shrimps (Crustacea: Decapoda) of the Albatross Philippine Expedition, 1907-1910. Smithsonian Institution Press - 1997 - si-pddr.si.edu
Used by permission. Many thanks to Charlies and Linda Raabe for their support. www.chucksaddiction.com