Lecture 7 – The Rhesus System (Part 1) PDF

Summary

This document provides an overview of the Rh blood group system, including its history, the genes involved (RHD and RHCE), and the associated proteins. It also discusses the different Rh phenotypes and how they are determined.

Full Transcript

SCIE 2040 – Transfusion Medicine 1 Textbook Chapter 5

Lecture 7 – The Rhesus System (Part 1)
5.1 History of Rh
In 1939, Levine and Stetson discovered an antibody suspected to cause hemolytic
disease of the fetus and newborn (HDFN), and a subsequent hemolytic transfusion
reaction, in a woman. They hypothesized that there was a “factor” in the husband’s
blood that was passed to the child, and that the mother was reacting to this “factor”.
The factor was later identified as the D antigen.
In 1941, Landsteiner and Wiener discovered an antibody produced by rabbits and
guinea pigs when they were exposed to rhesus monkey red blood cells. These
researchers went on to describe an antibody that reacted with 85% of the human
red blood cells against which it was tested. Although what they discovered in the
monkeys is now known as “anti-LW”, it was originally thought to be anti-D, and
thus “Rhesus” or “Rh” stuck as the name of the blood group system.

5.2 RHD and RHCE Genes and Proteins
The two Rh genes, RHD and RHCE, are located on chromosome 1.
The RHD gene (D/d) codes for the D antigen only. An individual with the D antigen
may be described as “D+” or “Rh(D)-positive.” If the D antigen is absent the
individual is usually described as “D-“ or “Rh(D)-negative.” The “d” allele is an
amorph; there is no d antigen. The absence of the D antigen occurs most commonly
when the RHD gene is deleted, however nonfunctional, mutated, or partial RHD
alleles also exist.
The RHCE gene codes for the RhCE protein that carries both the C/c and E/e
antigens. Note that “c” and “e” are indeed antigens, unlike “d”. Alleles of the RHCE
gene include RHCE, RHcE, RHCe, and RHce, with each coding for the respective
C/c and E/e antigens. The C and c proteins (and likewise the E and e proteins) differ
by just a handful of amino acids that extend outside of the RBC membrane,
allowing the body to potentially recognize these as foreign antigens.
Other, less common expressions of these antigens may occur from other point
mutations or from gene recombinations between both genes since the loci of the two
are in close proximity on chromosome 1.

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SCIE 2040 – Transfusion Medicine 1 Textbook Chapter 5

The Rh proteins
are
nonglycosylated
(unlike the ABO or
MNS blood group
antigens) meaning
that no
carbohydrates are
attached to the
protein. RhD and
RhCE are
multipass
proteins, each
passing through
the membrane a
dozen times. They
play structural
roles in the cell
and act as ion
channels. Text, Figure 5-1: Simple Schematic of the Rh and Rh-Associated Proteins

A third protein RhAG (Rh associated glycoprotein), coded for by the RHAG gene on
chromosome 6, is also required for proper Rh expression. RhAG is not part of the Rh
system, but without the protein multiple defects in the red blood cell membrane
occur.
Individuals who lack all Rh antigens (Rhnull phenotype) suffer from hemolytic
anemia. Amorphic-type Rhnull results from deletion of the RHD gene and a mutation
of the RHCE gene. Regulator type Rhnull results from mutations in the RHAG gene.
Relatives of a regulator-type Rhnull may express a milder form of Rh antigen
depression known as Rhmod.

5.3 Rh System Nomenclature
In 1986, Tippett postulated that Rh genetic expression was controlled by two closely
linked genes. This theory was later confirmed and expanded through molecular
analysis and identification of RHD and RHCE. However, prior to Tippett’s theory,
two other mechanisms of Rh inheritance were proposed. While neither was correct,
they gave rise to the Rh terminology still in use today.
5.3.1 Fisher-Race and Rosenfield
Fisher and Race suggested that there were three sets of alleles within the Rh
system (D/d, C/e, E/e) that they were so closely linked, all would be inherited

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together without an opportunity for crossing over. The Rh phenotype in Fisher-Race
terminology is expressed as the presence or absence of D, C, c, E and e antigens.
In 1962, Rosenfield proposed a corresponding numerical model for the Rh blood
group antigens by listing the antigens numerically in order of discovery:

Antigen D C E c e
Rosenfield # 1 2 3 4 5
A minus sign in front of the number indicated an individual tested negative for that
antigen, while no minus sign indicates they tested positive. For example:

Reaction with Corresponding Antisera Rosenfield Nomenclature
D C E c e
+ + 0 0 + Rh: 1, 2, -3, -4, 5
5.3.2 Wiener Haplotypes
Wiener postulated that individuals inherit Rh antigens as a product of a single gene
at a single locus. However, this single gene coded for an agglutinogen composed of
multiple antigens. The D antigen is referred to as Rh0(D) and he developed a
shorthand description of Rh haplotypes. The haplotypes and the corresponding
antigens are listed below in order from most to least frequently found amongst
those of European ethnicity.

Wiener: R1 r R2 R0 r’ r’’ Rz ry
Fisher-Race: DCe dce DcE Dce dCe dcE DCE dCE

Here is a helpful way to remember the corresponding antigens for a given
haplotype:
Big “R” corresponds to the D antigen. Little r means no D antigen (d).
The subscript or superscript corresponds to C/c and E/e:
Sub/superscript: 1 or ‘ 2 or “ Letter (z or y) 0 or no script
Antigen: Ce cE CE ce

5.4 Most Probable Genotype
Expanding on the previous table, below is each haplotype with its relative frequency
among different ethnic backgrounds:

Frequency (%) by Ethnicity R1 r R2 R0 r’ r’’ Rz ry
DCe dce DcE Dce dCe dcE DCE dCE
European 42 37 14 4 2 1