Bez názvu15 kopie
Structure of living matter
FG23_11ab o3_3
Lectures on Medical Biophysics
Department of Biophysics, Medical Faculty,
Masaryk University in Brno
FG04_28a-b

Bez názvu15 kopie
Lecture outline
•Water
•Properties of colloids
•Structure of proteins
•Structure of nucleic acids
•
•This lecture deals only with selected components of living matter with distinct biophysical
properties. Importance of some other components, e.g. electrolytes will be shown in the lecture on
bioelectric phenomena. Check on further information in textbooks of biology and biochemistry.

Bez názvu15 kopie
Water
o3_3
Molecules of water are strongly polar. Moreover, between the oxygen and hydrogen atoms of
neighbouring molecules, hydrogen bonds are formed. They join water molecules in aggregates –
clusters.

Bez názvu15 kopie
Hydrogen bonds between water molecules
FG11_20ab FG11_21
Liquid water
Pictures: http://cwx.prenhall.com/bookbind/pubbooks/hillchem3/medialib/media_portfolio/11.html
Ice

Bez názvu15 kopie
Colloids
•Colloids – also known as non-true solutions – the solution consists of solute particles of
diameter about 10 – 1000 nm dispersed in the solvent.
•We can distinguish two types of colloids according to the type of binding forces:
•
ØMicellar colloids (also associative, small particles are bound together by van der Waals bonds)
•
ØMolecular colloids (particles are macromolecules which subunits are bound together by covalent
bonds)

Bez názvu15 kopie
Weak chemical bonds
•Hydrogen bonds
•Hydrophobic interaction
•van der Waals bonds
van der Waals
•
Also London forces, sometimes not classified as van der Waals bonds

Bez názvu15 kopie
Properties of colloids
•Mechanical: rigidity, elasticity, viscosity – caused by covalent and weak chemical bonds
•These properties depend on the form of colloid:
•sol (liquid) or gel (solid). Gel formation = gelatinisation
•Optical:
–Light scatter: Tyndall effect (opalescence). Light can be scattered off the colloid particles.
Track of a light beam passing through a colloid is made visible by the light scattered by the
colloidal particles.
– Optical activity: Colloidal particles can rotate the plane of polarization of plane-polarised
light passing through the colloid
•Electrical: see lecture on instrumental methods in molecular biophysics

Bez názvu15 kopie
Tyndall effect in micellar and molecular colloids
gold4 620095mb_image002
- In solution of gelatin (a protein)
http://link.springer-ny.com/link/service/journals/00897/papers/0006002/620095mb.htm
- In solution of colloidal gold
http://mrsec.wisc.edu/edetc/cineplex/gold/

Bez názvu15 kopie
Types of Colloids - Biopolymers
•According to the affinity of the biopolymer to solvent (water)
–Lyophilic (hydrophilic) - form stable solutions
–Lyophobic (hydrophobic) - form unstable solutions
•According to the shape of the biopolymer (the shape is also influenced by the solvent!)
–Linear (fibrillar – DNA, myosin, synthetic polymers…..also scleroproteins, mostly insoluble in
pure water)
–Spherical (globular – haemoglobin, glycogen … also spheroproteins, mostly soluble in pure water)

Bez názvu15 kopie
Chemical composition of proteins
•According to the products of hydrolysis:
•simple (only amino acids in hydrolysate)
•conjugated (not only amino acids in hydrolysate)
ØNucleoproteins
ØHaemoproteins
ØFlavoproteins
ØMetalloproteins
ØLipoproteins
Ø…..
•(see Biochemistry)

Bez názvu15 kopie
Structure of proteins
•Structural units of proteins are amino acids (AA), connected by peptide bond:
•-RCH-NH-CO-RCH-,
•     which can hydrolyse:
•-RCH-NH-CO-RCH- + H2O  ¬¾®  -RCH-NH2   +   -RCH-COOH
•The carboxylic and amino groups can dissociate or protonise. E.g. the glutamic and asparagic acids
have one free carboxylic group:
•-COOH   ¬¾®   -COO- + H+
•AA lysine and arginine have one free amino group, which can protonise:
•-NH2 + H+    ¬¾®    -NH3+
•In proteins, 20 different AA can be found which can be divided into AA with polar and non-polar
side chain.
•AA with aromatic ring or heterocycle (phenylalanine, tyrosine, tryptophan) strongly absorb UV
light around 280 nm.
•AA cysteine contains sulphhydryl (thiol) group (-SH), which is oxidised by dehydrogenation and
connected with dehydrogenated group of another cysteine residue by covalent disulphidic bridge
(bond -S-S-).

Bez názvu15 kopie
Disulphidic bridges stabilise the protein structure (bovine ribonuclease A)
•http://cwx.prenhall.com/horton/medialib/media_portfolio/text_images/FG04_28a-b.JPG
Absorption spectrum of free phenylalanine, tyrosine and tryptophan in UV range
•According:http://www.fst.rdg.ac.uk/courses/fs460/lecture6/lecture6.htm
FG04_28a-b
Structure of proteins
Wavelength (nm)

Bez názvu15 kopie
Structure of proteins
•Primary (sequence of covalently bound AA residues)
•Secondary (mutual spatial arrangement of neighbouring links of the polypeptide chain – given
mainly by hydrogen bonds)
Øa-helix
Øb-structure (pleated sheet)
Øother
•Tertiary (spatial arrangement of the polypeptide chain as a whole – given by hydrophobic and
hydrogen bonds, stabilised by -S-S- bridges)
•Quaternary (a way of non-covalent association of individual polypeptide chains (subunits) in whole
of higher order)
ØHomogeneous – all subunits are identical
ØHeterogeneous – subunits of two or more kinds

Bez názvu15 kopie
•
•
•Podle: http://cwx.prenhall.com/horton/medialib/media_portfolio/text_images/FG04_10.JPG
protein structure
Rise per residue

Bez názvu15 kopie
b-structure (pleated sheet – antiparallel model)
http://www-structure.llnl.gov/Xray/tutorial/protein_structure.htm
betas.gif (5742 bytes)

Bez názvu15 kopie
Triple helix of collagen
http://cwx.prenhall.com/horton/medialib/media_portfolio/text_images/FG04_34.JPG
FG04_34

Bez názvu15 kopie
•Podle: http://cwx.prenhall.com/horton/medialib/media_portfolio/text_images/FG04_01.JPG
protein structures

Bez názvu15 kopie
Structure of nucleic acids (NA)
•Mononucleotide (the structural subunit of NA) is formed by:
ØPyrimidine (C, U, T) or purine (A, G) nitrogen base
ØSugar (ribose or deoxyribose)
ØPhosphoric acid residue
•
•DNA: up to hundreds thousands of subunits. M.w. 107 – 1012. Two chains (strands) form antiparallel
double helix.
•RNA:
Øm-RNA (mediator, messenger)
Øt-RNA (transfer)
Ør-RNA (ribosomal)
Ø(viral RNA, microRNA …… ?)

Bez názvu15 kopie
•http://cwx.prenhall.com/horton/medialib/media_portfolio/text_images/FG19_13_90035.JPG
double helix formation

Bez názvu15 kopie
B-DNA
http://cwx.prenhall.com/horton/medialib/media_portfolio/text_images/FG19_15aC.JPG
FG19_15aC

Bez názvu15 kopie
A-DNA – dehydrated, B-DNA – commonly present under physiological conditions, Z-DNA – in sequences
rich on CG pairs

Bez názvu15 kopie
Superhelical structure of circular DNA
•Podle http://cwx.prenhall.com/horton/medialib/media_portfolio/text_images/FG19_191C.JPG
superhelix

Bez názvu15 kopie
Structure of chromatin
http://cwx.prenhall.com/horton/medialib/media_portfolio/text_images/FG19_23_00742.JPG,
http://cwx.prenhall.com/horton/medialib/media_portfolio/text_images/FG19_25_00744.JPG
FG19_23_00742 FG19_25_00744

Bez názvu15 kopie
•Transfer RNA for valine – schematic
•t-RNA from yeasts  ↓
•http://cwx.prenhall.com/bookbind/pubbooks/hillchem3/medialib/media_portfolio/text_images/CH23/FG23
_14.JPG, http://www.imb-jena.de/cgi-bin/ImgLib.pl?CODE=4tra
IMB Jena Image Library Thumb Nail: 4TRA trna
Amino acid binding site
Valine
„Clover leaf structure“

Bez názvu15 kopie
Ribosomal RNA
•Next picture was published in: Science 11 February 2011: Vol. 331 no. 6018 pp. 730-736 in the
article: Crystal Structure of the Eukaryotic 40S Ribosomal Subunit in Complex with Initiation
Factor 1 (Julius Rabl, Marc Leibundgut, Sandro F. Ataide, Andrea Haag, Nenad Ban)
•
•Description:
•Architecture of the 40S. (A) Front and back views of the tertiary structure of the 40S showing the
18S rRNA as spheres and colored according to each domain (5′ domain, red; central domain, green; 3′
major domain, yellow; 3′ minor domain, blue; ESs, magenta), and the proteins as gray cartoons
(abbreviations: H, head; Be, beak; N, neck; P, platform; Sh, shoulder; Bo, body; RF, right foot;
LF, left foot). (B) Secondary structure diagram of the Tetrahymena thermophila (a protist)18S RNA
…showing the rRNA domains and the locations of the ESs. (C) Ribosomal proteins of the 40S are shown
as cartoons in individual colors; rRNA is shown as gray surface. The 40S is shown as in (A). (D)
View of the quaternary interactions between ES6 and ES3 at the back of the 40S. The RNA is
displayed as a cartoon with the proteins omitted for clarity. ES6 helices are colored in a gradient
from light to dark magenta and labeled from A to E... ES3 is highlighted in pink, and the rest of
the 18S rRNA is colored in gray. (E) The position of helix h16 in bacterial 30S [left…] and in 40S.

Bez názvu15 kopie http://www.sciencemag.org/content/331/6018/730/F1.large.jpg



Bez názvu15 kopie
MicroRNA (source: Wikipedia)
•MicroRNA or miRNA are single strand non-coding RNAs with a typical length of 21-23 nucleotides
which take a part in regulation of gene expression. miRNAs are produced by transcription from DNA
genes but they are not translated into proteins.
https://upload.wikimedia.org/wikipedia/commons/thumb/c/c4/MiRNA_processing.svg/250px-MiRNA_processi
ng.svg.png
•After modification by nucleases called „Drosha“ and „Pasha“ the pre-miRNA enters the cytoplasm
where can interact with the endonuclease called „Dicer“ forming miRNA. It is bound into the
RISC complex (RISC = RNA-induced silencing complex). Just the RISC is able to silence the gene
expression, which is known as RNA interference.

Bez názvu15 kopie
Conformation changes and denaturation of biopolymers
•Changes in secondary, tertiary and quaternary structure of biopolymers are denoted as conformation
changes.
•They can be both reversible and irreversible.
•‘native’ state of a biopolymer: its functional state. Otherwise the biopolymer has been
‘denatured’.

Bez názvu15 kopie
Denaturation factors
•Physical:
ØIncreased temperature
ØIonising radiation
ØUltrasound
Ø…..
•Chemical:
ØChanges of pH
ØChanges in electrolyte concentration
ØHeavy metals
ØDenaturation agents destroying hydrogen bonds – urea
Ø…..
•Combination of above factors: ionising radiation or ultrasound act directly and/or indirectly
(chemically via free radicals)

Bez názvu15 kopie
Author:
Vojtěch Mornstein
Content collaboration and language revision:
Carmel J. Caruana, Viktor Brabec
Presentation design:
Lucie Mornsteinová
Last revision and soundtrack added: September 2020