Lipids and Biological Membranes PDF

Summary

This chapter provides an overview of lipids and biological membrane structures, including the properties of fatty acids, triacylglycerols, and glycerophospholipids. It explains the functions of these lipids in biological systems, including their roles in energy storage and cellular signaling.

Full Transcript

Lipids and biological membranes:

Lipids are the fourth major group of molecules found in all cells. Lipds
are not polymeric unlike other macromolecules, however, they do
aggregate. Perform 3 biological functions. They are essential components
of biological membranes, lipids containing hydrocarbon chains serves as
energy storage, many cellular signaling involve lipid molecules.

Above is *Mycobacterium tuberculosis*, that causes tuberculosis. It
evades both human immune system and antibiotic drugs, due to thick cell
wall containing enormous lipid known as mycolic acid.

Lipids are substances of biological origin that are soluble in organic
solvents (chloroform, methanol). They can be separated
chromatographically and identified by mass spectrometry.

Lets see structural and functional properties of major classes of
lipids.

Fatty acids: these are carboxylic acids with long-chain hydrocarbon side
groups. They usually occur in esterified form as major component of the
various lipids.

Structural formula of some C~18~ fatty acids are shown here. The double
bonds all have the cis configuration.

The more common biological fatty acids are listed here. In higher plants
and animals , the predominant fatty acid residues are those of the C~16~
and C~18~ species: palmitic acid, oleic acid, linoleic acid and stearic
acid. Fatty acids with \20 carbon atoms are uncommon. Most
fatty acids have an even no. of carbon atoms because they are
biosynthesized by the catenation of C~2~ unit.

Unsaturated fatty acids contain double bonds, and are often
polyunsaturated (2 or more double bonds). ꞷ-3 and ꞷ-6 fatty acid are
example of important polyunsaturated fatty acid (e.g, α-Linolenic acid
and linoleic acid), nomenclature based on double bonded carbon atom as
counter from methyl terminal (ꞷ) end of the chain.

Saturated fatty acids are fully reduced, highly flexible and can assume
wide range of conformations.

The fats and oils that occur in plants and animals consist largely of
mixtures of triacylglycerols (triglycerides). These nonpolar,
water-insoluble substances are fatty acid triesters of glycerol.

**Triacylglycerol** acts as **energy** **reservoir** in animals and are
therefore their most abundant class of lipids.

Triacylglycerol differ in the placement of their 3 fatty acid residues.
Like shown here, 1-Palmitoleoyl-2-linoleoyl-3-stearoylglycerol.

Triacylglycerol functions as energy reservoir (are less oxidized than
carbohydrates and proteins and hence yield significantly more energy per
unit mass on complete oxidation). Fat provides about six times the
metabolic energy of an equal weight of hydrated glycogen.

In animals adipocytes (fat cells) are specialized for the synthesis and
storage of triacylglycerol. Figure shows scanning electron micrograph of
adipocytes. Each adipocyte contain a fat globule that occupies nearly
entire cell

Glycerophospholipids (or phosphoglycerides) are the major lipid
component of biological membranes. They consist of glycerol-3-phosphate
whose C1 and C2 positions are esterified with fatty acids. Also, the
phosphoryl group is linked to another usually polar group, X. In figure
a) is backbone, glycerol-3-phosphate. In b) the the general formula of
glycerophospholipids , R1 and R2 are long chain hydrocarbon chains of
fatty acids. Glycerol-3-phosphate and glycerophospholipids are chiral
compounds.

So, glycerophospholipids are amphiphilic molecules, with nonpolar
aliphatic (hydrocarbon) "tails" and polar phosphoryl --X heads.

The simplest glycerophospholipids, in which X = H, are phosphatidic
acids; present in small amount in biological membranes. Saturated C~16~
or C~18~ fatty acids usually occur at the C1 position and unsaturated
C~16~ to C~20~ at C2 position.

Individual glycerophospholipids are named according to the identities of
these fatty acid residues.

In figure. The glycerphospholipid
1-stearoyl-2-oleoyl-3-phosphatidylcholine is shown A) Molecular formula
in Fischer projection. B) Energy minimized space filling model with C
green, H white, N blue , O red, and P orange. Note that how the
unsaturated oleoyl chain is bent compared to the saturated stearoyl
chain.

The glycerophospholipid containing two palmitoyl chains
(Dipalmitoylphosphatidylcholine , DPPC)is an important component of lung
surfactant (the surface of the cell that form alveoli of luns are coated
with surfactants) and is essential for normal pulmonary function.

Phospholipases Hydrolyze Glycerophospholipids. Figure shows the action
of phospholipases. Phospholipase A~2~ hydrolytically excises the C2
fatty acid residues from a phospholipid to yield the corresponding
lysophospholipid. The bonds hydrolyzed by other types of phospholipases,
which are named according to their specifies are also indicated.

1,2 --Diacylglycerol, derived from membrane lipids by the action of
phospholipase C, is an intracellular signal molecule that activates a
protein kinase.

Phospholipase A~2~ is a small about 14 kD, protein, of about 125 amino
acid residues. Figure shows the model of phospholipase A~2~ and a
glycerophospholipid. The X-ray structure of the enzyme from cobra venom
is shown with space-filling model of dimyristoylphosphatidylethanolamine
in its active site as located by NMR methods. A Ca^2+^ ion in the active
site is shown in magenta.

Plasmalogens are glycerophospholipids in which the C1 subsituent of the
glycerol moiety is linked via an α, β- unsaturated ether linkage in the
cis configuration rather than through an ester linkage.

Ethanolamine, Choline and Serine form the most common plasmalogen head
group.

Sphingolipids are also major membrane components. Most of them are
derivatives of the C18 amino alcohol sphingosine, whose double bond has
the trans configuration.

The N-acyl fatty acid derivatives of sphingosine are known as ceramides.

Ceramides are the parent compounds of more abundant sphingolipids.

Sphingomyelins are ceramides bearing either a phosphotidylcholine or a
phophotidylethanolamine head group, (can be classified as
sphingophospholipids). They typically make up 10 to 20 mol % of plasma
membrane lipids.

Figure shows a sphingomyelin. A) molecular formula , B) Energy-minimized
space-filling model with C green , H white , N blue, O red and P orange.

This is electron micrograph of myelinated nerve fibres. Thin
cross-sectional view shows the spirally wrapped membranes around each
nerve axon. The myelin sheath may be 10-15 layers thick. Its high lipid
content makes it an electrical insulator.

Cerebrosides are ceramides with head groups that consist of a single
sugar residue. (like galactocerebrosides and glucocerebrosides)

Gangliosides are the most complex glycosphingolipids. They are ceramides
with attached oligosaccharides that include atleast one sialic acid
residue. The structure of gangliosides G~M1~, G~M2~ and G~M3~ (3 of the
100s). Are shown here. G~M2~ and G~M3~ differ from G~M1~ only by the
sequential absences of the terminal D-galactose and
N-acetyl-D-galactosamine residues. Other gangliosides have different
oligosaccharides head group.

Energy minimized space-filling model of G~M1~ with C green, H white, N
blue, and O red are shown here.

[Steroids] are mostly of [eukaryotic origin].
They are derivatives of cyclopentanoperhydrophenanthrene, a compound
that [consist of four fused nonplanar rings].

[Cholestero]l is the **most abundant steroid in animals**,
is further [classified as sterol] because of its [C3-OH
group]. A) Shows its [structural formula] with
the [standard numbering system]. And B) is Energy minimized
s[pace-fillin]g model with C green, H white, and O red.

Cholesterol is a [major component] of animal [plasma
membrane (constituting 30 -40%)] Its [polar OH
group] give sit a [weak amphiphilic character]
and [fused ring system provide greater rigidity].

Cholesterol [can] also [be] [esterified to long
chain fatty acids] **to form cholesterol esters** such as
cholesterol stearate.

**Plant** contain [little cholesterol] but [synthesize other
sterols.]

[In mammals cholesterol] is the **[metabolic precursor of
steroid hormones]**. They are classified according to
physiological response they evoke.

**Glucocorticoids** such as **[cortiso]l**, [effect
carbohydrate], [lipid] and [protein]
[metabolism], [influence inflammatory reactions]
and [capacity to cope with stress].

**Aldosterone** and other **[mineralocorticoids]** [regulate
excretion of salt and water by kidneys].

The **adrogens** and **estrogens** [effect sexual development and
function]. Testosterone is an adrogen (male sex hormone) and
β-estradiol is an estrogen (female sex hormone).

[The various forms of vitamin D] are hormones. They [are
sterol derivatives] in which the [steroid B ring is
disrupted between C9 and C10].

**Vitamin D~2~ (ergocalciferol)** is [nonenzymatically formed in the
skin of animals through the photolytic action of UV light on the plant
sterol ergosterol (a common milk additive]).

**Vitamin D~3~ (cholecalciferol**) is [similarly derived from
7-dehydrocholesterol] (hence the saying that [sunlight
provides vitamin D]).

[Vitamin D~2~ and D~3~ are inactive], the
[active] [form] are [produced] by
[addition of OH group] carried out [by liver and
kidney] to yield 1
α[,25-Dihydroxycholecalciferol]. **Active vitamin D
increases serum Ca^2+^** by promoting the intestinal [absorption of
dietary Ca^2+^. This] [increases] the
absorption of [Ca^2+^ in bones and teeth. ]

[Vitamin D deficiency in children produces **rickets**], a
disease characterized by [stunted growth and deformed
bones].

[Excessive intake of vitamin D] over long period results in
[vitamin D intoxication], the consequent [high serum
Ca^2^]^+^ results in [calcification of soft
tissues] and [development of kidney stones].

[Other lipids] perform a variety of metabolic roles.

**Isoprenoids** are [not-structural components of membranes]
built from [5-carbon units] with the [same carbon skeleton
as isoprene].

Like, isoprenoid, [ubiquinone] (also known as coenzyme Q,
[cofactor of mitochondrial respiratory complexe]s supporting
cellular bioenergetics.) Mammalian ubiquinone [consists of 10
isoprenoids units.]

[Over 50,000 isoprenoids] (called **terpenoids**), has been
[characterized in bacteria, fungus and plants]. **[Fat
soluble vitamins in vertebrae]** like (like vitamin D) is
**rich in isoprenoid compounds**. )

(vitamins are organic substances that animal require in small amounts
but cannot synthesize and hence must acquire in diet.)

**Vitamin A, retinol**, is [derived] from [plant product
β-carotene] (present in [green vegetables],
[carrots], [tomatoes]). **Retinol is oxidized to
retinal** which [functions as the eye's photoreceptor] at
low light intensities. [Deficiency] of vitamin A [can lead
to blindness].

[Retinoic acid] stimulates [tissue repair], used
to [treat acne] and [skin ulcers] and
[cosmetically to eliminate wrinkles].

**Vitamin K** is a lipid [synthesized by plants (as
phylloquinone]) and [bacteria (as menaquinone]).
[About half of the daily requirement for humans is supplied by
intestinal bacteria]. Vitamin K has **role in blood clotting
proteins**. Vitamin K [deficiency] prevents results [in
inactive clotting proteins] leading [to excessive
bleeding] ;

[Anti-coagulant drugs] are compounds that
[interfere] with [vitamin K function] (like [to
prevent clot formation after surgery]).

[**Vitamin** **E**] is **α-tocopherol**. It is incorporated
into cell membranes and **functions as antioxidant** that [prevents
oxidative damage] to membrane proteins and lipids.

[**Eicosanoids** are **Prostaglandins**] (lipid compounds),
[Thromboxanes], [Leukotrienes], and
[Lipoxins].

Eicosanoids [acts at a very low concentrations] and are
involved in the [production of pain and fever] and in the
[regulation of blood pressure], [blood
coagulation] and [reproduction].

In humans eicosanoids are [derived from Arachidonic acid a C~20~
compounds]. Arachidonate is stored in cell membranes as the
C2 ester of phosphatidyl inositol.

[Amphiphillic molecules] such as [soaps and
detergents] **form micelles** (globular aggregates whose
hydrocarbon groups are out of contact with water.

**Single tailed amphiphiles**, such as [soap anions], [form
spheroidal or ellipsoidal micelles] because of their tapered
shapes, [there hydrated head groups are wider than their
tails].

Figure shows aggregates of single-tailed lipids. [The tapered Van der
Waals envelope of these lipids] a) [permits]
them [to pack efficiently to form a spheroidal micelle], b)
The [diameter of the micelles depends on the length of the
tails]. Spheroidal micelles composed of many more lipid
molecules than the optimal no. c) [Would have been unfavorable
water-filled center (blue]). Such micelle [could flatten
out to collapse] the hollow centre, but as these ellipsoidal
micelles [become elongated].d) they [allow develop water
filed spaces].

The [**two** hydrocarbon **tails** of **glycerophospholipids** and
**sphingolipids** give these amphiphiles a somewhat **rectangular
cross-section**]. The steric requirements of packing such
molecules together yield large disklike micelles. These **lipid
bilayers** are around 60 A◦ thick.

[A suspension of phospholipids (glycerophospholipid or sphingomyelins)
can form **liposomes** ]**(**[closed, self-sealing
solvent-filled vesicles] that are bounded by only single
bilayer). Figure shows electron micrograph, accompanying figure consist
of a **lipid bilayer**.

[Lipid bilayers have fluid-like properties]. Figure shows
[phospholipid diffusion] in a lipid bilayer.

a\) **Transverse diffusion ( a flip-flop**) is defined as the
[transfer] of a [phospholipid molecule] from
[one bilayer leaflet to the other]. (it is an [extremely
rare event]), (have [half-time of several days or
more]).

b\) **[Lateral diffusion]** is defined as the [pairwise
exchange] of neighboring phospholipid molecule [in the same
bilayer leaflet]. Lipids are **highly mobile** in the plane
of the bilayer.

This is the model [snapshot of a lipid bilayer] at an
instant in time. The conformations of dipalmitoylphosphatidylcholine
molecules in a bilayer surrounded by water were [modelled by
computer] (molecular dynamics simulation).

The **fluidity** of bilayer is **temperature-dependen**t. As bilayer is
[cooled down below a characteristic transition temperature],
it [undergoes] a sort of [phase-chang]e.

Figure shows phase transition in a lipid bilayer. A) [above the
transition temperature] , both lipid molecules as a whole
and their nonpolar tails are [highly mobile] in the plane of
the bilayer. B) [Below the transition temperature] , the
lipid molecules [form] a [much more orderly array to yield a
gel like solid.]

C**holester**ol, which does [itself] [does not form a
bilayer], **decreases membrane fluidity** because its [rigid
steroid ring system interferes] [with the motion of the
fatty acid side chains] in other membrane lipids.

This is [X-ray] structure of the [integral membrane
protein] **aquaporin-O (AQPO)** in [association]
with [lipids]. The [protein] is represented by
its surface diagram, which is colored according to charge ([red
negative, blue positive and white uncharged]). Tightly
bound molecules of [dimyristoylphosphatidylcholin]e are
drawn in s[pace-filli]ng. The arrangement of the two rows of
lipid molecules, with phosphate-phosphate distance of 35 A◦, matches the
dimensions of a lipid bilayer.

[Human erythrocyte] **glycophorin A** is a [transmembrane
(TM]) protein, that is it [completely spans] the
membrane. The protein bears [15 o-linked oligosaccharides]
(green diamonds) and one that is [N-linked] (dark green
hexagon) in its extracellular domain. The predominant sequence of the
O-linked oligosaccharides is also shown (NeuNAc= N-acetylneuraminic
acid). **The protein's transmembrane portion (brown and purple) consists
of 19 sequential predominantly hydrophobic residues**. Its terminal
portion, which is located on the membrane's cytoplasmic face, is rich in
anionic (pink), cationic (blue), and polar (blue-gray) residues. There
are [two] common [genetic variants] of
glycophorin A. [Glycophorin A^M^ has Ser and Gly at position 1 and 5,
whereas glycophorin A^N^ has Leu and Glu at these
positions.]

[Nigel and Richard] used [electron
crystallography] to [determine] structure of
[integral membrane protein] **bacteriorhodopsin**, produced
[by archaebacterium] *Halobacterium salinarum*. It consists
largely of a bundle [of seven about 25 residues α-helical
rod]s that span the lipid bilayer perpendicular to the
bilayer plane. It **generates proton concentration gradient across the
cell membrane** that powers ATP synthesis. A covalently bound
[retinal] (drawn in [stick form]) is the
[protein's light absorbing group].

[Transmembrane] proteins [may contain
α-helices.] The figure shows the [identification of
transmembrane helices by hydropathy plots.]The **average of
the hydropathy indices** (hydrophobic and hydrophilic tendencies) **of
the amino acid residues** in a sliding window of defined length is
**plotted** **against** the **position of the first amino acid** in the
window. A [positive value] indicates that the [peptide
segment] in the window is h[ydrophobi]c, that is
its transfer to water would require an input of energy. [Segments of
\>20 hydrophobic residues] are [likely] [to form
TM helices]. The plots here are for a) glycophorin A and b)
bacteriorhodopsin. The bar above each plot and the square brackets
indicate the experimentally determined positions of the TM helices in
the corresponding protein. Note [that glycophorin a has only one TM
helix], whereas **bacteriorhodopsin has seven TM helices**.

[Some] [transmembra]ne proteins [contain
β-barrels]. β-barrels occur **in porins**.

This is the [X-ray] structure of E. coli [OmpF
porin]. This is the [ribbon diagram of 16 stranded monomer.
]

X-ray structure of E. coli [OmpF porin]. This is the [ribbon
diagram of the trimer] embedded in its semi-transparent
surface and viewed along its 3-fold axis of symmetry from cell's
exterior, [showing pore through each subunit.]

X-ray structure of E. coli OmpF porin. [A space filling model of the
trimer viewed perpendicular to its 3-fold axis].
[Trp] and [Tyr] [side] chains are
shown in [white]. [These groups delimits about 25 A◦ high
hydrophobic band (scale at right)] that is immersed in the
nonpolar portion of the bacterial outer membrane.

[Some membrane associated proteins contain] **covalently
attached lipids** that [anchor the protein to the membrane].

Prenylated proteins have covalently [attached lipids] that
are built from [isoprene] units. The [most common isoprenoid
groups are] the **C~15~ farnesyl** and **C~20~
geranylgeranyl** residues.

(**Prenylation** is a [post-translational modification]
where **lipid groups**, like [farnesyl or geranylgeranyl]
groups, are **added to proteins**)

The [most common prenylation site] in protein is [C terminal
tetrapeptide C-X-X-Y], where C is [cysteine] X
is often an [aliphatic amino] acid residue. Residue [Y
influences the type of prenylation]. The **prenyl group** is
**enzymatically** [linked] [to] the [Cys
sulfur] atom [via] a **thioether linkage**.
[X-X-Y tripeptide ins then proteolytically excised] and the
[newly exposed terminal carboxyl group is esterified with methyl
group].

Two kinds of fatty acids , myristic acid (myristoylation) and palmitic
acid (palmitoylation) are linked to membrane proteins.

**Glycosylphosphatidylinositol-linked proteins** (**GPI-linked**
proteins) [occur in all eukaryotes]. The [core
structure] of the GPI group consists of
p[hosphatidylinositol] **glycosidically linked to a linear
tetrasaccharide** composed of three mannose residues and one
glucosaminyl residue. The [mannose at the nonreducing end]
of this assembly [forms] a **phosphodiester bond with a
phophoethanolamine** residue [that is amide-linked] to the
[protein's C-terminal carboxyl group]. [R1 and R2 represent
fatty acid residues] whose identities vary with the protein.
The tetra saccharide may have a variety of attached sugar residues whose
identities also varies.

Role signal transduction, cell adhesion , immuine fuction etc.

[Plasma membrane] (membrane that separates and protect the
interior of the cell from outside). [Singer and Nicolson]
gave "[fluid mosaic model]". In this model, [integral
proteins are visualized as "ice bergs" floating in a two-dimensional
lipid "sea" in a random or mosaic distribution]. In figure ,
[Integral proteins (purple]) are embedded in a bilayer
composed of [phospholipids (blue] head groups attached to
wiggly tails) and [cholesterol (yellow]). The
[carbohydrate] components ([green and brown]
beads) of glycoproteins and glycolipids occur on only the [external
face] of the membrane. Most membranes contain a higher
proportion of protein than is depicted here.

[Integral proteins] **can diffuse laterally in the lipid
matrix**. Membrane fluidity can be [explained] by ;

[Fusion of mouse and human cells.] The accompanying
photomicrographs (the square boxes) were taken through filters that
allowed only red or green light to reach the camera.

The [**rates of diffusion of proteins in membranes** can be determined
from measurements of **fluorescence recovery after photobleaching**
(FRAP]). In this, a [fluorophore is specifically attached to
a membrane] component in an immobilized cell or in an
artificial membrane system. [An intense laser pulse focused on a very
small area destroys (bleaches) the fluorophore there].
**The rate at which the bleached area recovers its fluorescence** , as
**monitored** by [fluorescence microscopy] **indicates** the
**rate** at which unbleached and bleached fluorophore labeled molecules
laterally diffuse into and out of the bleached area.

The [membrane skeleton] helps define cell
[shape].

[Erythrocyte membrane can be obtained by osmotic lysis],
**which causes the cell content to leak out**. The [resulting membranous
particle are called erythrocyte ghost], **[because on
withdrawal of conditions they reseal to form original shape without
cytoplasm]**. The **protein spectrin** was in erythrocyte
ghost [accounting] for [75% of erythrocyte membrane
skeleton].. Spectrin has [two] polypeptide
chains, 280 kDa [α-subunit] and 246 kDa [β
subunit]. [Both] of the antiparallel
[polypeptide] contains multiple [106 --residue
repeats], which are though to [form] flexibly
connected [triple-helical bundles.] 2 of these heterodimers
join, head to head, to form an (αβ)2 heterotetramer.

The [X-ray] structure of three consecutive repeats of
chicken [brain α-spectrin]. Each of these repeats consist of
an [up-down-up triple-helical bundle] in which the
C-terminal helix of one repeat is continuous , via a 5 residue helical
linker (purple).

An [electron micrograph] of an [erythrocyte membrane
skeleton] that has been [stretched] to an area
[9 to 10 times greater] than that of the native membrane.
Streching makes it possible [to obtain clear images of the membrane
skeleton], which in its native state is densely packed and
irregularly flexed.

A [model of erythrocyte membrane skeleton] with inset
showing its relationship to the intact erythrocyte. The [junction
between spectrin tetramers include actin and tropomyosin]
and [band 4.1] protein (named after its position on SDS
PAGE).

[Spectrin] is [also associated] with [1880
residue protein ankyrin] **which binds to integral membrane
ion channel protein**. Ankyrin's N-terminal 798-residue segment consists
almost entirely of 24 tandem , [around 33 residue repeats known as
ankyrin repeats]. This is the [X-ray] structure
of human ankyrin repeats 13-24. N-terminus is blue, repeat 13 and
C-terminus is red, repeat 24.

The **interaction of membrane components with the underlying
cytoskeleton** helps [explain] **why** integral [membrane
proteins exhibit different degrees of mobility within] the
[membrane]. Figure shows the **model rationalizing the
various mobilities of membrane proteins**. [Protein A,]
which [interacts tightly] with underlying cytoskeleton , is
*[immobile]*. Protein [B] is [free to
rotate] within the confines of the cytoskeletal "fences".
Protein [C] [diffuses by travelling through
"gates] " in the cytoskeleton. The diffusion of membrane
proteins is not affected by the cytoskeleton.

[Membrane lipids are distributed asymmetrically]. Figure
shows asymmetric distribution of membrane phospholipids in the [human
erythrocyte membrane]. The phospholipid is expressed as mol
%.

In [eukaryotes], the [enzymes] that [synthesizes
membrane lipids are] mostly integral membrane
[protein] of the endoplasmic reticulum (**ER**). Figure
shows [electron micrograph of ER]. This membrane network is
contagious with the nuclear membrane. The so-called [smooth
ER] is the [site of synthesis membrane lipids],
and the **rough E**R, with its **associated ribosomes, is site of
synthesis of membrane and secretory proteins.**

[In Prokaryotes], [lipids] are
[synthesized] by integral membrane proteins in the [plasma
membrane]. To demonstrate this Kennedy and Rothmangave
[growing bacteria a 1 min pulse of ^32^PO~4~^3-^] in order
to [radioactively] label the [phosphoryl] groups
of only the [newly synthesized phospholipids]. Immediately
afterward, [they added trinitrobenzenesulfonic acid (TNBS]),
a membrane impermeable reagent that combines with
phophotidylethanolamine (PE).

The location of lipid synthesis in a bacterial membrane,. **Newly
synthesize PE was labelled by ^32^PO~4~^3-^ (yellow head groups**), and
the PE on the cell surface was independently labeld by treatment with
the [membrane-impermeable reagent TNBS]. When the TNBS
labeled (red circles) occurred immediately after the ^32^P pulse , none
of the ^32^P --labelled PE was TNBS labelled (upper right) thereby
indicating that the PE is synthesized on the cytoplasmic face of the
membrane. If however, there was even a few minutes delay between the two
labeling procedures, much of the TNBS-labelled PE in the external face
of the membrane was also ^32^P labelled.

The [secretory pathway generates] secreted and
[transmembrane proteins]. All secreted proteins are
synthesized [with leading N terminal] 1336 residue
**signal** **peptides**. These signal peptides consist of [6 to 15
residue hydrophobic core] flanked by several relatively
hydrophilic residues that usually include one or more basic residues
near the N-terminus. Figure shows the --terminus sequences of some
eukaryotic proteins, The hydrophobic core (tan) of most signal peptides
are **preceded by basic residues (blue**).

The [secretory pathway generates] secreted and transmembrane
[proteins]. Figure shows the secretory pathway. It depicts
ribosomal synthesis, membrane insertion and initial glycosylation. 1)
When [signal peptide is synthesized]. 2) **SRP** (signal
peptide recognition particle), **binds to signal peptide** and
**ribosome** and **polypeptide synthesis is inhibited**. 3)
[SRP-ribosome complex diffuse to RER and binds to SRP receptor in
complex with translocon.] 4) **SRP** and **SR**
**stimulate** each other **to hydrolyze their bound GTP to GDP**
resulting in **forming** **ribosome-translocon complex, this will resume
polypeptide synthesis**.

5\) When [signal peptide enters ER lumen], it is
[cleaved] from polypeptide [by signal
peptidase]. 6) **Enzymes in the ER lumen** initiates
**posttranslational** modification of polypeptide. 7) When the
polypeptide [synthesis] is [completed], it is
[released from translocon & ER] and then the [two subunits
of ribosome dissociates].

The channel forming component of [translocon] is a
[heterotrimeric protein] named **Sec61 in mammals** and
**SecY in prokaryotes**. Sec Y is shown here, It has [α, β and γ
subunit]. a) [X-ra]y structure of the complex.
B) [View] form the cytosol and c) Model for the insertion of
TM helix into a membrane. The translocon is viewed as in b). [A
polypeptide chain (yellow]) is shown [bound] in
the [translocon's pore] during its
[translocation] through the membrane, and a [signal-anchor
sequence (red) is shown passing through the translocon's lateral
gate] and being released into the membrane (arrow)

After their synthesis , [partially processed proteins appear in Golgi
apparatus]. In this array of flattened golgi apparatus
vesicles, newly synthesized transmembrane and secretory proteins
[undergo] **processing and sorting**. [Protein transit via
two mechanism]. **Anterograde**: forward(cis to trans face)
and vice versa called **Retrograd**e.

The posttranslational processing of proteins. Membrane, secretory and
lysosomal [proteins] are [synthesized] by
[RER-associated ribosomes] (gray dots; top). As they are
synthesized, the proteins (red dot) are either injected into the lumen
of the ER or inserted into its membrane. [After initial processing in
the ER] , the proteins are [encapsulated] in
[vesicles] that [bud off from the ER] membrane
and subsequently [fuse with the cis-golgi network (top]).
The proteins are [progressively **processed**] in the
[cis] , [medial] and [trans]
[cisternae] of the [golgi]. Finally in the trans
golgi network (bottom), the [completed glycoproteins] are
[**sorted** for **delivery**] to their final destinations,
the plasma membrane , secretory vesicles or lysosomes to which they are
[transported by yet other vesicles.]

Membrane, secretory and lysosomal proteins are [transported in in coated
vesicles] (vesicles in which proteins are transported
between the RER and different compartments of golgi[). 3
types] of coated vesicles are characterized by their
[protein coats.]

**Clathrin --coated vesicles** forms a [polyhedral framework around
vesicles], that [transport protein from Golgi to plasma
membrane].

**COPI coated vesicles**. Forms [fuzzy coating around
vesicles] and carry out [both anterograde and
retrograde] transport of proteins.

(insert show respective vesicles at higher magnification).

**COPII coated vesicles**. It [consists] of [two conserved
protein heterodimers]. It transport protein [from ER to the
golgi].

(insert show respective vesicles at higher magnification).

On arriving at its target membrane, a vesicle fuses with it, thereby
releasing its contents on the opposite side of the target membrane.

Shown here is [fusion of a vesicle with the plasma
membrane]. The [inside of the vesicle and the exterior of
the exterior of the cell are topologically equivalent].
Fusion of the vesicle with the plasma membrane [preserves the
orientation of the integral proteins embedded in the vesicle
bilayer] because the same side of the protein is always
immersed in the cytosol. Note that soluble proteins packaged inside a
secretory vesicle that fuses with the plasma membrane would be released
outside the cell.

The [clathrin] network is [build from proteins]
known as **triskelion**, this is an electron micrograph of triskelion.
The variable orientations of their legs are indicative of their
flexibility.

It is [cryo-EM based image]. It has [three heavy
chains] that each [bind] one of the two
homologues [light chains].

[Triskeleton assemble to form polyhedral cages]. This is
[showing three polyhedral structures] that are
[formed] [when] [triskeleton]
[assemble] into clathrin cages.

[After fusing with target membrane, vesicles may release its content.
]

Shown here is [Vesicle fusion at a synapse]. This is an
electron micrograph of a frog neurotransmitter synapse. Synaptic
vesicles are undergoing fusion (arrows) with the presynapytic plasma
membrane (top).

This process [discharges] the [neurotransmitter
contents] of the [synaptic vesicles] into the
[synapytic cleft], the space between the neuron and the
muscle cell (the postsynaptic cell).

[Protein] **SNAREs** [mediate vesicular fusion].
This is the [X-ray] structure of a [SNARE]
[complex] modelled [between two membranes]. The
[complex includes an R-SNARE] (blue, contain conserved
residues) and [Q-SNARE (red], contain conserved Gln
residues). And [SNAP-25 (green], a two Q domain containing
Q-SNARE), for a [total of four helices]. The **cleavage**
**site** for various costridial **neurotoxins** (**causing tetanus, and
botulism**) are indicated by arrows.

This a model for SNARE-mediated vesicle fusion. Here R-SNAREs and
Q-SNAREs are schematically represented by blue and red worms.

Zipping draws 2 membranes together,

Hemidiffusion, where bilayer leaflets fuse exposing interior.

Tension causes breakdown and forming fusion pore which then expends.

The major integral [protein] component of the
[membrane] **that envelops influenza virus** is named
**hemagglutinin (HA**). HA has [two peptides] designated as
**HA1** and **HA2**. Proteolytic removal of [HA's transmembrane helix
yield protein named BHA]. This is the X-ray structure of
influenza hemagglutinin. a) BHA [monomer] is shown , HA1 is
green and HA2 is cyan. B) BHA [trimer] shown.

HA undergoes dramatic conformational change , the nature of which was
elucidated by X-ray structure of a portion of BHA named TBHA2 that
consists of BHA's long helix and some of its flanking regions. This is
the [schematic diagram comparing the structures] of BHA and
TBHA2. This drawing indicates the positions and heights above the viral
membrane surface of TBHA2's various structural elements in the [HA
trimer (left)] and [in its low pH form] (right).
In the low pH form , the [fusion peptide would protrude well above the
receptor --binding heads where it would presumably insert itself into
the endosomal membrane.]