Basic data:
Scientific name: Xiphophorus maculatus (Günther; 1866)
Explanation of words: Xiphophorus (ksiphos = double-edged sword species, phoros = bearing / hint of gonopods in males /), (maculatus = spotted / belly /)
Slovenian name: Plati
Group: Livebirds
Source: Central America ; Mexico
Size: Males: 3-5 cm, females: 4-6 cm
Biotope / habitat : inhabits rivers on the Atlantic side of Central America
Social behavior: Quiet fish, group aquarium fish
Diet: Flakes, occasionally algae, insects, insect larvae, worms, ...
Cultivation: Easy
Aquarium: Minimum 50 liters
Population: 10-15 fish per 100 liters of water
Decoration: Dense planting, stones
Temperature: 20-27 ° C
pH: 7-8.2
Hardness: from 9 ° dGh to 20 ° dGh
Salinity max. 28.5 1,0 (1,021)
Lifespan: 3 years
Synonyms
Kingdom: Animalia / animals
Trunk: Chordata / string players
Class: Actinopterygii / arthropods
Order: Cyprinodontiformes / Toothpicks
Family: Poeciliidae / live-bearing toothed carp
Genus: Xiphophorus
Species: Xiphophorus maculatus
(Günther; 1866)
Xiphophorus maculatus
Pay
Platypoecilus maculatus / Günther, 1866
Poecilia maculata / Günther, 1866
Platypoecilus nigra / Brind, 1914
Platypoecilus pulchra / Brind, 1914
Platypoecilus rubra / Brind, 1914
Platypoecilus cyanellus / Meinken, 1935
Platypoecilus aurata / Stoye, 1935
Platypoecilus sanguinea / Stoye, 1935
Cultivation
Keep water around 24 ° C, do not like soft and acidic water.
The platypus can be inhabited along with most peaceful fish, is not as aggressive as its cousin cousin and even males get along just fine with each other.
Food
Pay is an omnivore by nature, takes almost everything from flakes, plant foods, larvae, frozen foods, etc.
Reproduction
Reproduction is characteristic of the family Poeciliidae .
The fish are ready for breeding at the age of six to eight weeks at a temperature between 24 and 26 ° C, in sufficient space and quality variegated diet. Adults are not as aggressive towards juveniles as guppies, and there are always enough young people when planting an aquarium. Algae are welcome as they are a food source for both adults and pups.
They pay lively, colorful and attractive. Today they exist in almost all colors and combinations. Around 1940, biologist dr. Myron Gordon (engaged in cancer research) during his experimental work crossed today the most common color version of a platya that had a black tail fin and a black muzzle.
An example of the habitat of a species
Wild dresses
The wild populations of Platia are widespread from the coast of southern Mexico (Vera Cruz, Chiapas, Tabasco and Campeche), to Guatemala and Belize.
The northern border is located in the Jamapa River Basin in the state of Vera Cruz in Mexico and stretches south to the Alta Verapaz region, the Petén district of Guatemala, and the vast Belize region.
Especially in the north (Japa, Cotaxtla, Otopa, Blanco, Tonto, Papaloapan, Coatzacoalcos San Juan, Dos Canos) the species is located up to 500 meters above sea level.
Hotspots with subtropical and tropical climates can be found in the geographical area of distribution of this species.
North of the geographical distribution of the species, for example in the Vera Cruz region, the average air temperature ranges between 20 ° C in January and 27 ° C in June. Nevertheless, average temperatures cannot give us a true picture of the local climate, as the warmest month of the year is not actually June, but April, May or September, depending on the region. Average water temperatures in many regions may be 0.4 ° C higher in August than in June.
In some regions, the highest temperatures are in April, when the sun is at its peak and the rainy season has not yet begun.
Rainfall, which begins in May, slightly cools the environment, lowers the highest temperatures, while slightly increasing the minimum.
In Belize, air temperatures range from 10 ° C to a maximum of 35 ° C, the annual average is 26 ° C with a small temperature range throughout the year and temperatures above 18 ° C even in winter.
The highest rainfall in the regions where the highest density of this species is is in summer, hurricanes occur between June and October in the north and from June to November in the south.
Water temperatures range from 24 to 30 ° C between April and October and between 16 and 24 ° C between November and March.
Xiphophorus maculatus lives mainly in rivers, canals and streams with slow water flow. However, many populations can be found in lakes, coastal lagoons and other standing water environments.
Usually, this species is more associated with sandy-bottomed biotopes, some underwater vegetation, and submerged trunks of felled trees.
Adults are more likely to enter environments with greater depths, which do not exceed 1 meter in depth.
His favorite environment is characterized by clean water, although the water rocks during the flood season.
The pH value of water is between 7.5 and 8.1 or more.
In other parts of the world, where the species has been introduced by humans, populations settle in roughly the same environment or near hot springs, where they are protected from severe cold that would otherwise be fatal to them.
Source: http://www.viviparos.com/
Pay phenotypes
The phenotype occupies the visual characteristics of the species (body shape, colors and their distribution, behavior, ..).
It is influenced by the genotype and the environment in which they live.
Currently 18 phenotypes are known:
1. Xiphophorus maculatus , Jp 163 A
2. Xiphophorus maculatus , Jp 163 B
3. Xiphophorus maculatus , Belize Platy II
4. Xiphophorus maculatus , Coatzacoalcos Platy
5. Xiphophorus maculatus , Jp30R
6. Xiphophorus maculatus , Nigra
7. Xiphophorus maculatus , Papaloapan Platy
8. Xiphophorus maculatus , Sex Reversal
9. Xiphophorus maculatus , SpSr
10. Xiphophorus maculatus , Usumacinta Platy
11. Xiphophorus maculatus , Wild Jamapa Platy
12. Xiphophorus maculatus , XSrAr
13. Xiphophorus maculatus , YSdDr
14. Xiphophorus maculatus , YSdSr
15. Xiphophorus maculatus , JpYBr
16. Xiphophorus maculatus , JpYIr
17. Xiphophorus maculatus , JpYIrBr
18. Xiphophorus maculatus , YSp
Source: https://www.researchgate.net/publication/228480117_The_Xiphophorus_Genetic_Stock_Center_Manual
https://www.xiphophorus.txstate.edu/Xiphophorus-Stocks.html
Biology
In a study published in 1977 by Klaus D. Kallman and Valerie Borkoski, entitled “A sex-linked gene that controls the onset of sexual maturity in female and male platypus ( Xiphophorus maculatus), fertility in females and adult size in males ”, we are aware of some very important differences in sexual maturity and fertility.
Platforms of both sexes are known to reach sexual maturity between 5 and 73 weeks of age, depending on their genetic heritage (Kalman and Borkoski, 1977).
As with other known species of the subfamily Poeciliinae, animals of both sexes have the same growth rate, but males slow down or virtually stop development from sexual maturity onwards, those that reach this level remain lower than those later.
Under the same maintenance conditions in the aforementioned study, males from different study populations reached sexual maturity on average with different ages and sizes. In one of the studied populations, this phase occurred at 21 mm, corresponding to 8 weeks, the other observed populations reached the same developmental stage between 25 and 29 mm, i.e. about 11 to 13.5 weeks. On the other hand, males from one of the populations stopped growing only at 37 mm, which is approximately at 26.5 weeks of age (Kalman and Borkoski, 1977).
Another important difference between populations that can be observed mainly between those coming from Mexico and those from Belize is the fact that there are two different types of gender determination mechanisms in the species.
Three sex-linked chromosomes (W, X, and Y) have been identified in the natural population, so the sexual genotype of females may be WY or WX, and in males XY or YY, (Kallman 1973).
By genotype is meant the genetic content (or specific genome) of an individual in the form of DNA.
In Platius from the northern part of the range (Mexico) the male is heterogamous (XX - female, XY - males), in the southern part (Belize) and among most native genera the female is heterogamous (WY - female, YY male), (Mac Intyre, 1961).
As with other species of the genus Xiphophorus, countless pieces of evidence of sexual reversion have emerged over time (the individual functionally belongs to one sex and genetically the opposite).
Although not very common, this phenomenon occurs mainly in captive-bred populations of unknown origin. These strains usually include in their genetic material traces of crossbreeding between different varieties and populations, so their value as a subject of scientific research is questionable.
Contrary to popular belief, it is not enough to have only females left in one aquarium for one to become male or vice versa.
In nature, these fish are omnivorous and feed on almost all living organisms of suitable dimensions, namely zoobenthos and zooplankton, aquatic invertebrates, insects, but with a wide variety of plant substances (especially plant debris and algae).
In addition to lyophilized flake food, shrimp, mosquito larvae, tubifex, daphnia, all live or frozen are highly recommended.
In captivity, cannibalism is rare and appears to be a very effective signal for food and environmental shortages.
Of course, in limited environments such as small aquariums that have no shelter for the young, adult fish that are improperly fed and accustomed to seeing the young as food will certainly take every opportunity to get an accessible form of live food.
The period between litters usually ranges between 26 and 29 days, with a 28-day cycle being very common. This duration is closely related to temperature and food.
Fertilization occurs about a week after birth.
Younger females have 20 to 40 offspring, and fully developed even more than 60.
Sterility has been observed in females of this species.
Presumably, these are internal causes, namely a phenomenon equivalent to ovarian degeneration or another organic cause, so that animals affected by this health problem stop reproducing.
This species poses no problem at the behavioral level and can be included in any mixed aquarium as long as aggressive species or predators do not endanger its safety.
Disputes between males are completely harmless to the remaining inhabitants of the same aquarium and they rarely cause physical consequences.
In the early 1920s, it was found that some species of the genus Xiphophorus could be crossed very easily. Their hybrids are characterized by the fact that they are often fertile and give offspring.
This phenomenon is so common that it is not good to have different species of this genus in the same aquarium.
The result of crosses, shows the characteristics of both species, the fact is that the fish are intermediate in appearance. Thus, it is possible to determine some dominant characteristics of one or even two species in a single hybrid in generation F1, and so on.
As a result of these experiments, hybrids sometimes occur that show established originality in relation to the parent species. Certain traits inherited from only one of the original species may show special vigor in this mixed offspring.
In both the U.S. and Germany, scientists soon noticed that some crossbreeding results during Xiphophorus led to a special incidence of melanoma, one of the most deadly skin cancers.
These melanomas are due to problems in the formation of melanistic markings that occur in the pigment of some hybrids.
Apparently, this provided researchers with an excellent starting point in the fight against cancer.
Based on these phenomena, there have even been some models and systems that have become instruments of essential utility in studying the progression of melanoma.
Interestingly, the pigmented cells in these fish are prone to developing diseases that are biochemically, morphologically, and physiologically comparable to those in humans.
The methods used in platia also include radiation, which gives scientists insight into the incidence of this type of cancer and its development.
Through the next generations of animals treated in the laboratory, researchers can see the progression of melanoma through a phenomenon called genetic expectation.
These well-known aquarium fish of ours have become powerful instruments in the study of heredity in this type of disease.
