Nucleomorphs are small, vestigial eukaryotic nuclei found between the inner and outer pairs of membranes in certain

plastid A plastid is a membrane-bound organelle found in the Cell (biology), cells of plants, algae, and some other eukaryotic organisms. Plastids are considered to be intracellular endosymbiotic cyanobacteria. Examples of plastids include chloroplasts ...

s. They are thought to be vestiges of red and green algal nuclei that were engulfed by a larger eukaryote. Because the nucleomorph lies between two sets of membranes, nucleomorphs support the endosymbiotic theory and are evidence that the plastids containing them are complex plastids. Having two sets of membranes indicate that the plastid, a prokaryote, was engulfed by a eukaryote, an alga, which was then engulfed by another eukaryote, the host cell, making the plastid an example of secondary endosymbiosis.

Organisms with known nucleomorphs

As of 2007, only two

monophyletic In biological cladistics for the classification of organisms, monophyly is the condition of a taxonomic grouping being a clade – that is, a grouping of organisms which meets these criteria: # the grouping contains its own most recent co ...

groups of organisms are known to contain plastids with a vestigial nucleus or nucleomorph: the cryptomonads of the supergroup

Cryptista Cryptista is a clade of alga-like eukaryotes. It is most likely related to Archaeplastida which includes plants and many algae, within the larger group Diaphoretickes. Other characteristic features of cryptophyte mtDNAs include large syntenic ...

and the chlorarachniophytes of the supergroup Rhizaria, both of which have examples of sequenced nucleomorph genomes. Studies of the genomic organization and of the molecular phylogeny have shown that the nucleomorph of the cryptomonads used to be the nucleus of a

red alga Red algae, or Rhodophyta (, ; ), make up one of the oldest groups of eukaryotic algae. The Rhodophyta comprises one of the largest Phylum, phyla of algae, containing over 7,000 recognized species within over 900 Genus, genera amidst ongoing taxon ...

, whereas the nucleomorph of the chlorarchniophytes was the nucleus of a

green alga The green algae (: green alga) are a group of chlorophyll-containing autotrophic eukaryotes consisting of the phylum Prasinodermophyta and its unnamed sister group that contains the Chlorophyta and Charophyta/ Streptophyta. The land plants ( ...

. In both groups of organisms the plastids originate from engulfed photoautotrophic

eukaryote The eukaryotes ( ) constitute the Domain (biology), domain of Eukaryota or Eukarya, organisms whose Cell (biology), cells have a membrane-bound cell nucleus, nucleus. All animals, plants, Fungus, fungi, seaweeds, and many unicellular organisms ...

s. Of the two known plastids that contain nucleomorphs, both have four membranes, the nucleomorph residing in the periplastidial compartment, evidence of being engulfed by a eukaryote through

phagocytosis Phagocytosis () is the process by which a cell (biology), cell uses its plasma membrane to engulf a large particle (≥ 0.5 μm), giving rise to an internal compartment called the phagosome. It is one type of endocytosis. A cell that performs ph ...

. In 2020, genetic work identified the plastid in '' Lepidodinium'' and two previously undescribed dinoflagellates ("MGD" and "TGD") as being most closely related to the green alga '' Pedinomonas''. The observation of a nucleomorph in ''Lepidodinium'' is controversial, but MGD and TGD are proven to have DNA-containing nucleomorphs. The transcriptomes of the nucleomorphs have been sequenced. One slight issue in understanding the sequence of evolution is that although the phylogenetic tree built from Lepidodinium-MGD-TGD's plastid is monophyletic, the tree built from their host-nucleus DNA is not, implying that they might have acquired very similar algae independently. File:2023 Cryptomonad.svg, Representation of a Cryptomonad File:2023 Chlorarachniophyte.svg, Representation of a Chlorarachniophyte

Structure

A cryptomonad nucleomorph is typically much smaller than the host nucleus. A relatively large portion of its size is devoted to the

nucleolus The nucleolus (; : nucleoli ) is the largest structure in the cell nucleus, nucleus of eukaryote, eukaryotic cell (biology), cells. It is best known as the site of ribosome biogenesis. The nucleolus also participates in the formation of signa ...

, which contains its own ribosomes and rRNA. There seems to be nuclear pores observable by imaging, but genetic work has failed to find any protein appropriate for forming the nuclear pore complex. There is one nucleomorph per plastid. The nucleomorph divides before the accompanying plastid. The dividing nucleomorph lacks a mitotic spindle, and the nucleomorph envelope persists throughout division. Between the plastid and the cytoplasm of the host there are four membranes: the inner and outer membranes of the chloroplast, the periplastid membrane, and the epiplastid membrane. The epiplastid membrane is encrusted with ribosomes (in cryptomonads) and is in many ways similar to a

endoplasmic reticulum The endoplasmic reticulum (ER) is a part of a transportation system of the eukaryote, eukaryotic cell, and has many other important functions such as protein folding. The word endoplasmic means "within the cytoplasm", and reticulum is Latin for ...

, hence the name "chloroplast endoplasmic reticulum" (cER). Plastid-targeted proteins encoded in the host genome must cross all four membranes to reach the plastid. First they use classic secretory

signal peptide A signal peptide (sometimes referred to as signal sequence, targeting signal, localization signal, localization sequence, transit peptide, leader sequence or leader peptide) is a short peptide (usually 16–30 amino acids long) present at the ...

s to cross the epiplastid membrane. Then the symbiont-specific ERAD-like machinery (SELMA) – encoded in the nucleomorph as a repurposed ERAD – pulls the protein from the epiplastid space (or the lumen of the cER) into the periplastid space (the cytoplasm of the symbiote). The standard chloroplast transit peptide then acts to cross the remaining two layers via TIC/TOC complex. The chlorarachniophytes, on the other hand, has no such thing as a cER, hence the initial import into the epiplastid space must occur by some other mechanism. It's only known that their plastid-targeted proteins are prefixed by both a signal peptide and a chloroplast-targeting peptide much like cryptomonads. Based on research done on apicomplexa, which also has 4 membranes but no cER, it's possible that the protein is first sent into the ER, then sent to the epiplastid space by the endomembrane sorting system. Some sort of a pore may then move the peptide into the periplastid space, but there seems to be no SELMA-like pore in this group. It's only known that the TIC/TOC complex exists for crossing the last two layers.

Nucleomorph genome

Nucleomorphs represent some of the smallest genomes ever sequenced. After the red or green alga was engulfed by a cryptomonad or chlorarachniophyte, respectively, its genome was reduced. The nucleomorph genomes of both cryptomonads and chlorarachniophytes converged upon a similar size from larger genomes. They retained only three chromosomes and many genes were transferred to the nucleus of the host cell, while others were lost entirely. Chlorarachniophytes contain a nucleomorph genome that is diploid and cryptomonads contain a nucleomorph genome that is tetraploid. The unique combination of host cell and complex plastid results in cells with four genomes: two prokaryotic genomes (

mitochondrion A mitochondrion () is an organelle found in the cell (biology), cells of most eukaryotes, such as animals, plants and fungi. Mitochondria have a double lipid bilayer, membrane structure and use aerobic respiration to generate adenosine tri ...

and

of the red or green algae) and two

eukaryotic The eukaryotes ( ) constitute the Domain (biology), domain of Eukaryota or Eukarya, organisms whose Cell (biology), cells have a membrane-bound cell nucleus, nucleus. All animals, plants, Fungus, fungi, seaweeds, and many unicellular organisms ...

genomes (nucleus of host cell and nucleomorph). The model cryptomonad '' Guillardia theta'' became an important focus for scientists studying nucleomorphs. Its complete nucleomorph sequence was published in 2001, coming in at 551 Kbp. The ''G. theta'' sequence gave insight as to what genes were retained in nucleomorphs. Most of the genes that moved to the host cell involved protein synthesis, leaving behind a compact genome with mostly single-copy “housekeeping” genes (affecting transcription, translation, protein folding and degradation and splicing) and no mobile elements. The genome contains 513 genes, 465 of which code for protein. Thirty genes are considered “plastid” genes, coding for plastid proteins. It has three chromosomes with eukaryotic telomeres subtended by rRNA. The genome sequence of another organism, the chlorarachniophyte '' Bigelowiella natans'' indicates that its nucleomorph is probably the vestigial nucleus of a green alga, whereas the nucleomorph in ''G. theta'' probably came from a red alga. The ''B. natans'' genome is smaller than that of ''G. theta'', with about 373 Kbp and contains 293 protein-coding genes as compared to the 465 genes in ''G. theta''. ''B. natans'' also only has 17 genes that code for plastid proteins, again fewer than ''G. theta''. Comparisons between the two organisms have shown that ''B. natans'' contains significantly more introns (852) than ''G. theta'' (17). ''B. natans'' also had smaller introns, ranging from 18-21 bp, whereas ''G. theta''’s introns ranged from 42-52 bp. Both the genomes of ''B. natans'' and ''G. theta'' display evidence of genome reduction besides elimination of genes and tiny size, including elevated composition of adenine (A) and thymine (T), and high substitution rates.

Persistence of nucleomorphs

There are no recorded instances of vestigial nuclei in any other secondary plastid-containing organisms, yet they have been retained independently in the cryptomonads and chlorarachniophytes. Plastid gene transfer happens frequently in many organisms, and it is unusual that these nucleomorphs have not disappeared entirely. One theory as to why these nucleomorphs have not disappeared as they have in other groups is that

introns An intron is any Nucleic acid sequence, nucleotide sequence within a gene that is not expressed or operative in the final RNA product. The word ''intron'' is derived from the term ''intragenic region'', i.e., a region inside a gene."The notion of ...

present in nucleomorphs are not recognized by host spliceosomes because they are too small and therefore cannot be cut and later incorporated into host DNA. Nucleomorphs also often code for many of their own critical functions, like transcription and translation.Curtis, Bruce et al.
Algal genomes reveal evolutionary mosaicism and the fate of nucleomorphs
" ''Nature'' 492 :59-65 Some say that as long as there exists a gene in the nucleomorph that codes for proteins necessary for the plastid’s functioning that are not produced by the host cell, the nucleomorph will persist. The cryptomonad nucleomorph also codes for genes that function in plastid maintenance. In cryptophytes and chlorarachniophytes all DNA transfer between the nucleomorph and host genome seems to have ceased, but the process is still going on in a few dinoflagellates (MGD and TGD).

Tertiary endosymbiosis

The standard nucleomorph is the result of secondary endosymbiosis: a cyanobacterium first became the chloroplast of ancestral plants, which diverged into green and red algae among other groups; the algal cell is then captured by another eukaryote. The chloroplast is surrounded by 4 membranes: 2 layers resulting from the primary, and 2 resulting from the secondary. When the nucleus of the algal endosymbiont remains, it's called a "nucleomorph". Most tertiary endosymbiosis events end up with only the plastid retained. However, in the case of dinotoms (i.e. those having

diatom A diatom (Neo-Latin ''diatoma'') is any member of a large group comprising several Genus, genera of algae, specifically microalgae, found in the oceans, waterways and soils of the world. Living diatoms make up a significant portion of Earth's B ...

endosymbionts), the symbiont's nucleus appears to be of normal size with a large amount of DNA, surrounded by plenty of cytoplasm. The symbiont even has its own DNA-containing mitochondria. As a result, the organism has two eukaryotic genomes and three prokaryotic-derived organelle genomes.Tertiary Endosymbiosis in Two Dinotoms Has Generated Little Change in the Mitochondrial Genomes of Their Dinoflagellate Hosts and Diatom Endosymbionts - PLOS
/ref>

References

External links

Insight into the Diversity and Evolution of the Cryptomonad Nucleomorph GenomeCryptophyta at NCBI taxbrowserCercozoa at NCBI taxbrowser
---- According to GenBank release 164 (Feb 2008), there are 13

Cercozoa Cercozoa (now synonymised with Filosa) is a phylum of diverse single-celled eukaryotes. They lack shared morphological characteristics at the microscopic level, and are instead united by phylogeny, molecular phylogenies of rRNA and actin or Ubiqu ...

and 181

Cryptophyta The cryptomonads (or cryptophytes) are a Class (biology), superclass of algae, most of which have chloroplast, plastids. They are traditionally considered a Division (taxonomy), division of algae among phycologists, under the name of Cryptophyta ...

entries (an entry is the submission of a sequence to the DDBJ/EMBL/GenBank public database of sequences). Most sequenced organisms were: Guillardia theta: 54; Rhodomonas salina: 18; Cryptomonas sp.: 15; Chlorarachniophyceae sp.:10; Cryptomonas paramecium: 9; Cryptomonas erosa: 7. {{Protist structures Organelles Plant physiology Mitochondrial genetics Microbiology Algae Phycology Evolution Symbiosis Endosymbiotic events