s in plant cells.
Chloroplasts, proplastids, and differentiation In
land plants, the plastids that contain
chlorophyll can perform
photosynthesis, thereby creating internal chemical energy from external
sunlight energy while capturing carbon from Earth's atmosphere and furnishing the atmosphere with life-giving oxygen. These are the
chlorophyll-plastidsand they are named
chloroplasts; (see top graphic). Other plastids can synthesize
fatty acids and
terpenes, which may be used to produce energy or as raw material to synthesize other molecules. For example, plastid
epidermal cells manufacture the components of the tissue system known as
plant cuticle, including its
epicuticular wax, from
palmitic acidwhich itself is synthesized in the chloroplasts of the
mesophyll tissue. Plastids function to store different components including
starches,
fats, and
proteins. All plastids are derived from proplastids (also named proplasts), which are present in the
meristematic regions of the plant. Proplastids and young chloroplasts typically divide by
binary fission, but more mature chloroplasts also have this capacity. Plant
proplastids (undifferentiated plastids) may
differentiate into several forms, depending upon which function they perform in the cell, (see top graphic). They may develop into any of the following variants: •
Chloroplasts: typically green plastids that perform
photosynthesis. •
Etioplasts: precursors of chloroplasts. •
Chromoplasts: coloured plastids that synthesize and store pigments. •
Gerontoplasts: plastids that control the dismantling of the photosynthetic apparatus during
plant senescence. •
Leucoplasts: colourless plastids that synthesize
monoterpenes. Leucoplasts differentiate into even more specialized plastids, such as: • the
aleuroplasts; •
Amyloplasts: storing
starch and detecting
gravityfor maintaining
geotropism. •
Elaioplasts: storing
fats. •
Proteinoplasts: storing and modifying
protein. • or
Tannosomes: synthesizing and producing
tannins and
polyphenols. Depending on their morphology and target function, plastids have the ability to differentiate or redifferentiate between these and other forms.
Plastomes and Chloroplast DNA/ RNA; plastid DNA and plastid nucleoids Each plastid creates multiple copies of its own unique genome, or
plastome, (from 'plastid genome')which for a chlorophyll plastid (or chloroplast) is equivalent to a 'chloroplast genome', or a 'chloroplast DNA'. The number of genome copies produced per plastid is variable, ranging from 1000 or more in
rapidly dividing new cells, encompassing only a few plastids, down to 100 or less in mature cells, encompassing numerous plastids. A plastome typically contains a
genome that encodes
transfer ribonucleic acids (
tRNA)s and
ribosomal ribonucleic acids (
rRNAs). It also contains proteins involved in photosynthesis and plastid gene
transcription and
translation. But these proteins represent only a small fraction of the total protein set-up necessary to build and maintain any particular type of plastid.
Nuclear genes (in the cell nucleus of a plant) encode the vast majority of plastid proteins; and the expression of nuclear and plastid genes is co-regulated to coordinate the development and
differention of plastids. Many plastids, particularly those responsible for photosynthesis, possess numerous internal membrane layers. Plastid DNA exists as protein-DNA complexes associated as localized
regions within the plastid's inner envelope
membrane; and these complexes are called 'plastid
nucleoids'. Unlike the nucleus of a eukaryotic cell, a plastid nucleoid is
not surrounded by a nuclear membrane. The region of each nucleoid may contain more than 10 copies of the plastid DNA. Where the proplastid (
undifferentiated plastid) contains a single nucleoid region located near the centre of the proplastid, the
developing (or differentiating) plastid has many nucleoids localized at the periphery of the plastid and bound to the inner envelope membrane. During the development/ differentiation of proplastids to chloroplastsand when plastids are differentiating from one type to anothernucleoids change in morphology, size, and location within the organelle. The remodelling of plastid nucleoids is believed to occur by modifications to the abundance of and the composition of nucleoid proteins. In normal
plant cells long thin protuberances called
stromules sometimes formextending from the plastid body into the cell
cytosol while interconnecting several plastids. Proteins and smaller molecules can move around and through the stromules. Comparatively, in the laboratory, most cultured cellswhich are large compared to normal plant cellsproduce very long and abundant stromules that extend to the cell periphery. In 2014, evidence was found of the possible loss of plastid genome in
Rafflesia lagascae, a non-photosynthetic
parasitic flowering plant, and in
Polytomella, a genus of non-photosynthetic
green algae. Extensive searches for plastid genes in both
taxons yielded no results, but concluding that their plastomes are entirely missing is still disputed. Some scientists argue that plastid genome loss is unlikely since even these non-photosynthetic plastids contain genes necessary to complete various
biosynthetic pathways including heme biosynthesis. Even with any loss of plastid genome in
Rafflesiaceae, the plastids still occur there as "shells" without DNA content, which is reminiscent of
hydrogenosomes in various organisms. ==In algae and protists==