There is no known public figure or notable individual named Eukaria Figota. It is possible that this person may not be widely recognized or may not exist.
Sililo Figota was born in 1965.
Atigi figota
Archaea, Eukaria, Bacteria
No , these are not in a phylum , these are separate kingdoms but in same domain Eukaria .
The three main classification domains are Bacteria, Archaea, and Eukarya. This system categorizes all living organisms into these three domains based on their cellular structure and genetic makeup.
Yes! All multi-cellular organisms contain specialized cells. Specialization is the reason they become multi-cellular. Multi-cellular organisms are differentiated from other eukaria and prokaria in that, rather than living individually or in convenient colonies, they MUST be multi-cellular to survive.
Butterflies are insects and arthropods, and all arthropods belong to the taxonomic domain of Eukarya, members of which are characterised by having cells with nuclei. Eukarya covers all organisms in the Kingdom Animalia, as well as the Kingdoms Plantae, Fungi and Protista.
Technically an animal cell is a special kind because unlike plant cells which are rectangular in shape animal cells are normally a circular shape which are designed that way because circles are able to maneuver around each other so that the organism can move while plant cells that are rectangular and stiff can not move very quickly.
Archaea (prokaryotic organisms which live in extreme environments)Bacteria (prokaryotic organisms, includes most disease-causing microorganisms)Eukaryote (eukaryotic organisms, contains the 5 kingdoms of Protista, Fungi, Plantae, Animalia, and Monera)
In biology, a domain is the highest taxonomic rank of organisms, above the kingdom level. There are three domains of life: Bacteria, Archaea, and Eukarya, each representing a distinct evolutionary lineage. Organisms within the same domain share similar cellular structures and biochemistry.
Samoa has won twelve medals at the Commnwealth Games; 3 silvers (Paul Wallwork-1974 Men's 82.5kg Combined (Weightlifting), Bob Gasio-1996 Men's Light Middleweight (Boxing) and Ofisa Ofisa-2002 Men's 85kg Clean and Jerk (Weightlifting)and 9 bronze (Vai Samu-1974 Men's Heavyweight (Boxing), Faitala Fiso Su'a-1978 Men's Light Heavyweight (Boxing), Ropati Vipo Samu-1978 Men's Light Middleweight (Boxing), Richard Betham-1978 Men's Middleweight (Boxing), Sililo Figota-1990 Men's Light Middleweight (Boxing), Emerio Fainuulua-1990 Men's Heavyweight (Boxing), Ofisa Ofisa-2002 Men's 85kg Combined (Weightlifting), Niusila Opeloge-2002 Men's 85kg Snatch (Weightlifting) and Warren Fuiava-2006 Men's Middleweight (Boxing).
It is my understanding that often eukariotic (multicellular organisms like humans) genes do not "work"(that is, cannot be translated) in prokariotes(bacteria) because bacteria are very very simple compaired to eukaria. Eukaria have complecated structures and mechanisms for the transcription and translation of DNA, bacteria only have plasmids and ribosomes. However, we have been able to get bacteria to use some human genes, most notably the gene to make insulin. Because eukariotic DNA has introns(random, useless segments of DNA) that are removed by special machinery before it is transcribed, scientists must remove all of the introns before inserting the DNA into the bacteria. They do this by obtaining mRNA from a human before it is transcribed in the ribosome, and using the enzyme reverse transcriptase(an enzyme in retroviruses such as HIV) to reverse transcribe the mRNA into cDNA("complementary" DNA that does not contain introns). cDNA can be spliced into a bacterium, and we can often make the genes "work" in bacteria. To answer the question, the genetic code is the same in every organism, so we can make human genes work in bacteria.