1. 10. Plastids Chloroplast Amyloplast Leucoplast Chromoplast (from greek plastikos: “molded”) Chloroplast Amyloplast Leucoplast Chromoplast
Rapid Changes in plastid shape Fig 1-43 Light micrograph of plastids with thin, tubular stromule extensions
All plastids are developmentally related to proplastids Plastid developmental cycle and the inter-conversion of various plastid types
Fig. 1-45. TEM showing a proplastid (left) adjacent to a mitochondrion in a bean root cell
TEM illustrating phytoferritin deposits inside a proplastid in a root apical meristem cell of soybean
2) Amyloplasts are starch-storing plastids : Unpigmented plastids that resemble proplastids but contain strach granules.
S: starch granules TEM of amyloplasts containing many starch granules (S)
3) Several categories of plastid are named for their color - Leucoplast are colorless plastids involved in the synthesis of monoterpenes, the volatile compounds
TEM showing leucoplasts (L) in an active secreting glandular trichome of pepperment.
Etioplast TEM of an etioplast PR: large prolamellar body T: associated unstacked thylakoids EN: envelope membrane
An early stage of grana thylakoid development in a greening etioplast PR An early stage of grana thylakoid development in a greening etioplast PR: prolamellar body
Chloroplasts GT: grana thylakoids ST: stroma thylakoids
Chromoplast (yellow, orange, or red….) TEM of chromoplast of a ripe fruit of Jerusalem cherry. The dense bodies in the plastid contain carotenoids (or xanthophylls)
4) The outer and inner membrane of the plastid envelope differ in composition, structure and transporter functions Rich in galactolipids, poor in phopholipids Out memebrane: nonspecific pore protein pass size : 10 kd Inner membrane: specific transporters pass small uncharged
5) The photosynthetic grana and stroma thylakoid membranes form a physically continuous three-demensional network
TEM depicting a single granum and associated stroma thylakoids
The spatial relationship between stacked granna and interconnecting stroma thylakoids
TEM revealing difference in grana and stroma thylakoids PS II PS I and ATP synthase TEM revealing difference in grana and stroma thylakoids
6) Plastids are partially autonomous, encoding and synthesizing some of their own proteins
7) Plastids reproduced by division of existing plastids TEM of dividing etioplast
8) Plastids are inherited maternally in most flowering plants but paternally in gymnosperms
9) Plastids synthesize chlorophylls, cartenoids and fatty acids and reduce some inorganic nutrients
Mitochondria : contain the respiratory machinery that generates ATP
TEM of a mitochondrion in a bean root tip cell
Similarity in the basic architecture of all mitochondria reflects the university of their mechanism for generating energy
An unusual phopholipid component of inner mitochondrial membrane
TEM depicting a longitudinal section through a transfer cell mitochondria Arrows indicate ribosomes
2) Small solutes cross the outer and inner mitochondrial membranes sequencially, whereas large proteins destined for matrix cross both membrane simultaneously
3) Mitochondria resemble prokaryotes in numerous important properties. Mitochondria possess the genetic capacity to make some of their own proteins. Mitochondrial ribosomes resemble those of prokaryotes. Mitochondria reproduce by fission.
TEM of a mitochondrion in a bean root tip cell, showing the final phase of division
4) Like plastids, mitochondria are semiautonomous and possess the genetic machinery to make some of their own proteins Distinctive features of plant mitochondria genome 1. large size and complexity (about 10 fold larger than animal ones) 2. Genome: do not contain a set of tRNA genes (16 tRNAs specific to 12-14 amino acids) 3. Contains some chloroplast DNA sequences (tRNA genes, but not functional)