McGill BIOL200 Nucleo-Cytoplasmic Transport Fall 2023 PDF

Summary

This document is a lecture about nucleo-cytoplasmic transport from a McGill BIOL200 class in Fall 2023. It details the process of molecules moving between the nucleus and the cytoplasm. The document is a lecture, not a past paper, and provides an overview of the molecular mechanisms involved.

Full Transcript

McGill

BIOL200 - Fall 2023

Nucleo-Cytoplasmic Transport

© R. Roy, 2023

McGill

BIOL200 - Fall 2023

Nuclear pore complexes resemble baskets, and
are the sites of nucleocytoplasmic transport

Cytoplasmic face

Nucleoplasmic face

© R. Roy, 2023

McGill

BIOL200 - Fall 2023

The nuclear pore complex is a highly ordered structure

• It’s huge: 125 megadaltons or
30x bigger than a ribosome.
• Composed of ~50 (yeast) to
~100 (vertebrates) different
proteins.
• Molecules up to ~40-60 kDa
can freely diffuse through the
NPC. Bigger molecules and
multimolecular complexes
(RNPs) must be transported.

© R. Roy, 2023

McGill

BIOL200 - Fall 2023

Transport through the NPC depends on
reversible hydrophobic interactions

FG nucleoporins are hydrophobic
and possess disordered domains

© R. Roy, 2023

McGill

BIOL200 - Fall 2023

Protein import through the NPC

• All nuclear proteins are synthesized in the cytoplasm
and imported through NPCs.
• These proteins contain a nuclear localization signal
(NLS).

© R. Roy, 2023

McGill

BIOL200 - Fall 2023

Addition of an NLS to a cytoplasmic protein
targets it to the nucleus

pyruvate kinase

NLS-pyruvate kinase
© R. Roy, 2023

McGill

BIOL200 - Fall 2023

Proteins required for nuclear import
• Ran: a monomeric G protein that exists in two conformations; one
bound to GTP and another when bound to GDP.

• Nuclear Transport Receptors: (Importins) these proteins bind to
NLS domains present on cargo proteins to facilitate transport through
the pore by associating with FG repeats on the nucleoporins.
© R. Roy, 2023

McGill

BIOL200 - Fall 2023

Mechanism for nuclear import of NLS-containing cargo proteins

High
concentration
Import complex

Low
concentration
Import complex

Low concentration
RanGTP/Importin
complex

High concentration
RanGTP/Importin
complex

© R. Roy, 2023

McGill

BIOL200 - Fall 2023

Exportin 1 uses a similar Ran-mediated mechanism

© R. Roy, 2023

McGill

BIOL200 - Fall 2023

Some RNAs are exported through
association with Ran
• Exportin t functions to export tRNAs. It binds fully
processed tRNAs and Ran-GTP and passes through
NPCs. The complex dissociates in the cytosol when it
interacts with Ran-GAP.
• Export of ribosomal subunits requires Ran.

• Some specific mRNAs that associate with particular
hnRNP proteins (HIV Rev for example) can be exported
through association with Ran.
• Most mRNAs are exported in a Ran-independent process
using an mRNA exporter.

© R. Roy, 2023

McGill

BIOL200 - Fall 2023

A simple model of mRNP export
Transport of the mRNP through the NPC is Ran-independent

•

Consists of two subunits
(NXF1/NXT1).
-Together they bind RNA
cooperatively with specific
mRNP proteins including
the SR proteins.
-They form a domain that
interacts with FG repeats
in nucleoporins.

© R. Roy, 2023

McGill

BIOL200 - Fall 2023

mRNP packaging in Balbiani Rings
Insect polytene chromosomes
(Balbiani Rings) provide a system
where transcription and mRNP
export can be microscopically
imaged.

Chironomous tentans

© R. Roy, 2023

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BIOL200 - Fall 2023

Model of mRNP export

ribosomes

Since ribosomes associate with the mRNA while it is still
being exported, the 5’ end must be exported first.

© R. Roy, 2023

McGill

BIOL200 - Fall 2023

Model of mRNP export
•

Only fully spliced
mature mRNAs get
exported; mechanisms
of this restriction are
not fully understood.

• This phenomenon may
be associated with the
activity of a protein
Cytoplasmic
bound to a nucleoporin
remodelling
that actively blocks premRNAs from leaving the
nucleus

RNA Helicase

© R. Roy, 2023