Rh Phenotyping. Exercise 4. Discussion. Textbook: Blaney, Chapter 5. Skills: 20 Points. Objectives:

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Exercise 4 Textbook: Blaney, Chapter 5 Skills: 20 Points Objectives:. List 4 reasons for determining an individuals Rh phenotype. 2. State the antigens of the Rh blood group system. 3. Describe the allele d. 4. Define the following terms: amorph, dominant, codominant, heterozygous, and homozygous as they relate to inheritance of the Rh antigens. 5. Define the terms phenotype and genotype as they relate to blood group antigens. 6. Briefly state the procedure whereby an individual s Rh phenotype is determined. 7. Recall each of the 8 Rh genes in both Fisher-Race and Wiener notation. 8. Given an Rh phenotype list the potential genotypes in both Wiener and Fisher-Race notations. 0. Determine the Rh phenotype and probable genotype of two (2) patient samples. Discussion In this procedure, commonly tested antigens of the Rh system will be studied. Normally the only Rh antigen identified in routine pretransfusion testing is the D antigen. Four additional Rh antigens which may be tested for are: C, E, c, and ç. Phenotyping for these antigens may be useful in: family studies, resolution of antibody problems, population studies, cases of disputed parentage, and to predict whether the sexual partner of a woman with Rh antibodies is likely to transmit genes that will result in offspring negative for the particular antigen. The Rh system initially appears simple and straightforward since it involves only five (5) antigens (C, c, E, ç, and D), but it is in fact one of the more complicated human blood group systems known. The gene complex is inherited and individuals may be analyzed in terms of separate antigens: D or its absence (d), C or c, and E or ç. Gene D is dominant to its allele d, because gene d is an amorph which makes no detectable antigenic product. The alleles C and c, and E and ç are codominant and if both alleles are present, both will be expressed. Wiener theorized that the Rh antigens displayed by an individual are the result of only a pair of genes, one inherited from each parent. If these are identical, the individual is homozygous for that gene and all the products of the gene will be expressed in a double dose on the person's red cell. When the genes inherited from each parent are not identical, the person is heterozygous for two different genes and, since the Rh genes are codominant, the products of both will be expressed on the person's red cells. Antigens that are products of both genes will be present in double dose, while those produced by only one of the pair of genes will be present in single dose. EXAMPLE: DCe/DCE (slash separates the gene) transmitted from each parent antigen D = homozygous, present on both sides antigen C = homozygous, present on both sides antigens ç and E = heterozygous, present in onsei de only MLAB 243

A phenotype is the assortment of antigens actually detectable on an individual's red cells using selected antiserums. In many blood group systems, the phenotype is an exact expression of the genotype. Unfortunately, this is not the case in the Rh system. Since any one antigen may derive from any of several genes, identifying antigens does not always allow the genotype to be deduced with certainty. Presumptions regarding the most probable genotype rest on knowledge of the frequency with which particular antigenic combinations derive from a single gene complex. To determine the genotype with more certainty, it is necessary to do family studies which are not always possible. The following is an example of a phenotype and the possible genotypes which could be present. EXAMPLE: Phenotype (antigens detected on the red cells) is: D, C, c, e Possible Genotypes Possible Genotypes (Fisher-Race) (Wiener) D C ç /d c ç R / r D C ç /D c ç R / R o D c e/dcç R /r' o In the general population, the most common D positive genotype is R /r. The most common D negative genotype is rr. MLAB 243 2

Principle The Rh phenotype is determined by testing the patient red blood cells with the five standard antiserums: anti-d, anti-c, anti- c, anti-e, and anti-ç. If the antigen to which the antiserum is directed is present, agglutination of the red blood cells will occur. No agglutination of the red blood cells indicates the absence of the antigen. Based on the reactions with these serums, certain statistical assumptions are made, not always correctly. For instance, if a cell reacts with anti-c but not with anti- c, the antigen C is assumed to be present in a double dose (homozygous for C). The exceptions to this are rare, but may be significant in paternity testing. In the past the reagent antiserums were made from individuals who have developed an antibody against a specific blood group antigen. Although human source anti-serums are still available, the move is to provide these reagents from clones. Agglutination of an individual's red cells by a specific antiserum indicates the presence of the corresponding antigen. No agglutination indicates its absence. MLAB 243 3

Reagents. Blood Bank Reagent Rack (See Procedure 3) 2. Anti-C, Anti-E, Anti-e, Anti- c, Rh control 3. Blood Bank plastic pipets 4. Blotting squares (biowipes) 5. 2x75 test tubes 6. Serofuge 7. Heat Block 8. Agglutination viewer 9. Squirt bottle of 0.85% saline 0. Sharpie Procedure. Refer to the ABO/D typing laboratory to set up tubes for the ABO/D type. 2. Label a tube for the each Rh typing sera with the patient's first and last initial and the Rh anti-sera to be tested. (anti-e, anti-e, anti-c and anti-c ). 3. CAREFULLY place one drop of the correct typing sera in the properly labeled tube for that anti-sera.. 4. Place one () drop of the 4-6% patient cell suspension to each forward type tube and to each of the Rh typing tubes (anti-e, anti-e, anti-c and anti-c ). 5. Centrifuge for 5-20 seconds. 6. Gently resuspend cell button and examine for macroscopic agglutination. 7. Grade the agglutination reaction and immediately record the results while observing the tube reaction in your hand. 8. CONFIRM YOUR REACTIONS WITH YOUR INSTRUCTOR by respinning the tubes and having instructor verify the results. Recording Results Record the reactions of the individual's cells with each appropriate antiserum. RECORD THE REACTIONS BY HOLDING THE TUBE IN FRONT OF THE CORRECT COLUMN, visually inspect and write your interpretation. Determine the individual's phenotype and most probable genotype in the appropriate spaces. See example provided. Use the attached chart for assistance. MLAB 243 4

Interpretation of Results Once the results of antigen typings have been obtained, the most probable genotype must be determined. At first this will be confusing and difficult, but interpretation will get easier with practice. The following example may help. Results obtained: anti-d anti-c anti-c anti-e anti-e 4+ 4+ 4+ 0 4+ Positive reactions indicate the presence of the antigen, negative reactions indicate the absence of the antigen. The phenotype of this patient (antigens detectable on the rbc) is: D, C, c, e. An Rh gene complex consists of a D or d, C or c, E or e antigens is inherited from each parent. When a patient is D positive the phenotype of the person is either D/d (heterozygous for D) or D/D ( homozygous for D). Make a separate column for each possible genotype, the other Rh antigens will be added to this base type. Heterozygous D Homozygous D D /d D /D The results from the Rh phenotype indicates that the patient is C+ and c+, the individual is heterozygous for the C antigen, so place a C or c on either side of the Dd as follows. It is critical to remember to list ALL possible combinations. DC /dc DC /Dc (only combination possible) Dc /dc The next antigen to plug in is E. The patient is E=e+ indicating that this individual is homozygous for e, so e will be present on both sides. DCe /dce Dce /dce DCe /Dce You must now convert the Wiener notations to Fisher-Race using the chart supplied, also indicate the frequencies in which these genotypes occur: DCe /dce R r 33% Dce /dce 0 R r <0.% DCe /Dce 0 R R 2% One thing to remember is that frequencies given are for the white population. In the black population the R 0 genotype is very common. It is critical to know the race of the individual when determining most probable genotypes. MLAB 243 5

Interpreting Results Memorize this chart! Antigens Fisher-Race Wiener D,c,e D c o ç R D,C,e DCç R D c E D c 2 E R D,C,E DCE R z c, ç d c ç r C,ç d C ç r' c, E d c E r " C,E dce r y In interpreting reactions for genotypes, always remember that if the D antigen is present it does not mean that it is homozygous. Figure the genotype with D on one side and d on the other (heterozygous for D). Use the chart on the following page and select the genotype with the highest frequency. For example, if the D, C, c and ç antigens are present, there are three (3) possible genotypes: Fisher-Race Wiener % frequency from following table. DCç /d c ç R /r 33% 2. DCç /D c ç R /R o 2% 3. D c e/dcç R /r' 0.0-0.% o The most probable genotype is R r since this has the highest statistical probability. MLAB 243 6

Rh Genotypes and Their Serological Reactions Genotypes Reactions with anti- Caucasian Frequency (%) Fisher-Race Wiener D C E c e DCe/dce R /r + + 0 + + 33 DCe/Dce 0 R /R + + 0 + + 2 Dce/dCe 0 R /r' + + 0 + + DCe/DCe R /R + + 0 0 + 8 DCe/dCe R /r' + + 0 0 + * DcE/dce 2 R /r + 0 + + + Dce/dcE 0 R /r" + 0 + + + DcE/Dce 2 0 R /R + 0 + + + * DcE/DcE 2 2 R /R + 0 + + 0 2 DcE/dcE 2 R /r" + 0 + + 0 * DCe/DcE 2 R /R + + + + + 2 DCe/dCE y R /r + + + 0 + DCe/dcE R /r" + + + + + DcE/dCE 2 y R /r + + + + 0 DcE/dCe 2 R /r' + + + + + * DCE/DCE z z R /R + + + 0 0 DCE/DCe z R /R + + + 0 + * DCE/DcE z 2 R /R + + + + 0 DCE/dCe z R /r' + + + 0 + DCE/Dce z 0 R /R + + + + + DCE/dcE z R /r" + + + + 0 DCE/dce z R /r + + + + + * DCE/dCE z y R /r + + + 0 0 Dce/dCE 0 y R /r + + + + + Dce/dce 0 R /r + 0 0 + + 2 Dce/Dce 0 0 R /R + 0 0 + + dce/dce r'/r 0 + 0 + + * dce/dce r'/r' 0 + 0 0 + dce/dce r"/r 0 0 + + + * dce/dce r"/r" 0 0 + + 0 dce/dce r'/r" 0 + + + + dce/dce y r /r 0 + + + + dce/dce y r /r" 0 + + + 0 dce/dce y r /r' 0 + + 0 + dce/dce y y r /r 0 + + 0 0 dce/dce r/r 0 0 0 + + 5 * = less than percent but greater than 0. percent = less than 0. percent but greater than 0.0 percent = less than 0.0 percent MLAB 243 7

Comparison of Wiener and Fisher-Race Concepts of the Rh Blood Group System Wiener Concept Gene Agglutinogen Blood Factors Gene Complex Fisher-Race Concept Blood Factors Approximate Frequency in Caucasoids of New York City (%) 0 R Rho Rh 0, hr', hr" Dce D, c, e 2.5 R Rh Rh 0, rh', hr" DCe D, C, e 5.2 2 R Rh2 Rh 0, rh", hr' DcE D, c, E 6.5 z R Rhz Rh 0, rh', rh" DCE D, C, E 4.9 r rh hr', hr" dce c, e 3.4 r' rh' rh', hr" dce C, e. r" rh" rh", hr' dce c, E 0.4 y r rhy hr', hr" dce C, E 0.02 MLAB 243 8

Name Date Exercise 4: Recording Results A. ABO/D Typing Forward Type D Type Weak D Test Reverse Type. Patient Name ID Number Anti-A Anti-B Anti-D *D Ctrl Wk D cells Wk D ctrl cells A Cells B Cells Interpretation 2. B. Rh Phenotype - circle the most probable genotype. COPY D TYPING from chart above DO NOT repeat. Instructor verified Reactions with anti- Most probable genotype Name D C E c e Rh ctrl Phenotype Fisher-Race Wiener Example 3+ 3+ O 3+ 3+ O D,C, c e DC e /d c e R r. # 2. # MLAB 243 9

Name Study Questions. List the antigens of the Rh system. (2.5 points) 2. State three situations in which testing for the Rh antigens (phenotyping) provides useful information. (.5 points). a. b. c. 3. Is the allele to D actually detected? Explain. ( point) 4. What does it mean to say that the Rh antigens C and c or E and e are codominant. ( point) 5. What is meant by the terms homozygous and heterozygous? (2 pts) 6. Define phenotype. ( point) MLAB 243 0

7. Define genotype. ( point) 8. State the most common D positive genotype in both Fisher-Race and Wiener notations. Provide the same for the most common D negative genotype. (2 points) Fisher-Race Wiener D positive D negative 9. How are presumptions regarding the most probable genotype determined? ( point) 0. Fill in the following chart and memorize! Fisher Race Wiener a. R DcE b. c. R z dce d. e. R 0 dce f. g. r dce h. MLAB 243

. For the following phenotypes, list all possible genotypes. State each ones' statistical probability as given for Caucasians. (Use Fisher-Race and Wiener.) Circle the most probable genotype. Point values vary. a. D, C, E, ç (3 points) b. d, c, ç ( point) c. D, E, c, ç (3 points) 2. State 2 situations in which a D control must be run AND THE REASON FOR RUNNING IT.(2 points) MLAB 243 2

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