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Blood, Vol. 94 No. 6 (September 15), 1999:
pp. 1840-1847
Ig V Gene Mutation Status and CD38 Expression As Novel Prognostic
Indicators in Chronic Lymphocytic Leukemia
By
Rajendra N. Damle,
Tarun Wasil,
Franco Fais,
Fabio Ghiotto,
Angelo Valetto,
Steven L. Allen,
Aby Buchbinder,
Daniel Budman,
Klaus Dittmar,
Jonathan Kolitz,
Stuart M. Lichtman,
Philip Schulman,
Vincent P. Vinciguerra,
Kanti R. Rai,
Manlio Ferrarini, and
Nicholas Chiorazzi
From the Department of Medicine, North Shore University Hospital and
NYU School of Medicine, Manhasset, NY; the Department of Medicine, Long
Island Jewish Medical Center and the Albert Einstein College of
Medicine, New Hyde Park, NY; and the Division of Clinical Immunology,
Istituto Nazionale per la Ricerca sul Cancro, Dipartmento Oncologia
Clinica e Sperimentale, Universita di Genova, Genova, Italy.
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ABSTRACT |
Cellular immunophenotypic studies were performed on a cohort of
randomly selected IgM+ B-chronic lymphocytic leukemia
(B-CLL) cases for which Ig VH and VL gene
sequences were available. The cases were categorized based on V gene
mutation status and CD38 expression and analyzed for treatment history
and survival. The B-CLL cases could be divided into 2 groups. Those
patients with unmutated V genes displayed higher percentages of
CD38+ B-CLL cells ( 30%) than those with mutated V
genes that had lower percentages of CD38+ cells
(<30%). Patients in both the unmutated and the 30%
CD38+ groups responded poorly to continuous multiregimen
chemotherapy (including fludarabine) and had shorter survival. In
contrast, the mutated and the <30% CD38+ groups
required minimal or no chemotherapy and had prolonged survival. These
observations were true also for those patients who stratified to the
Rai intermediate risk category. In the mutated and the <30%
CD38+ groups, males and females were virtually equally
distributed, whereas in the unmutated and the 30%
CD38+ groups, a marked male predominance was found. Thus,
Ig V gene mutation status and the percentages of CD38+
B-CLL cells appear to be accurate predictors of clinical outcome in
B-CLL patients. These parameters, especially CD38 expression that can
be analyzed conveniently in most clinical laboratories, should be
valuable adjuncts to the present staging systems for predicting the
clinical course in individual B-CLL cases. Future evaluations of new
therapeutic strategies and drugs should take into account the different
natural histories of patients categorized in these manners.
© 1999 by The American Society of Hematology.
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INTRODUCTION |
B CELL CHRONIC lymphocytic leukemia
(B-CLL) is the most common leukemia in the Western world1;
~7,500 individuals develop and  5,000 die of this disease each
year.2 Age is an important factor, as the incidence of
B-CLL increases linearly with each decade above the age of
40.3,4 In addition, gender is relevant because men
outnumber women by ~ 2:1 ratio and may have a worse clinical
outcome.5,6
Patients with B-CLL follow heterogeneous clinical courses. Some survive
for prolonged periods without requiring definitive therapy, while
others die rapidly despite aggressive treatment.1,7 Two
major staging systems have been developed to address this clinical
heterogeneity.8-10 Although these systems have provided valuable information regarding survival, they have been unable to
accurately predict which early stage or intermediate risk patients will
experience an indolent or an aggressive course. Therefore, novel
identifiers of the clinical subsets with favorable versus poor
prognoses would be very helpful for patient management. For this
reason, several parameters such as lymphocyte doubling
time,11 circulating levels of
 2microglobulin12,13 and soluble
CD23,14 serum thymidine kinase levels,15,16
bone marrow histology,17 and cytogenetic
abnormalities18 are currently being evaluated as adjuncts
to these staging systems.
B-CLL is characterized by the clonal accumulation of CD5+ B
cells.19 Although these cells originally were considered
antigen-inexperienced "virgin" lymphocytes, recent data indicate
that at least half of these cases represent expansions of
previously-triggered, postgerminal center (GC) "memory" B
cells.20,21 This conclusion is based on the presence of
significant numbers of somatic mutations in the Ig heavy (H) chain
variable region (V) genes. Indeed, in our previous study of 83 (64 IgM+ and 19 non-IgM+) B-CLL
cases,21 we found significant numbers of VH
gene mutations in ~50% of the IgM+ and ~75% of the
non-IgM+ (IgG and IgA) cases. We recently extended these
studies to the VL genes of these cases. These newer
analyses indicate that ~10% of B-CLL patients have mutations in
their VL genes only (Ghiotto et al, in
preparation). Taken together, these VH and
VL sequencing data suggest that ~60% of B-CLL cases can
be considered post-GC memory B cells. Thus, B-CLL cases can be divided
into 2 categories according to Ig V gene mutation status.
The expression of specific cell surface markers distinguishes subsets
of normal human B cells that differ in differentiation and activation
stages and in biologic properties.22 Analyses of CD38 and
IgD expression have been especially useful in distinguishing B cells at
various stages of differentiation from naïve through memory
cells.23 Therefore, in this study, we investigated whether the mutated and unmutated B-CLL cases could also be distinguished in
this way. In addition, we asked whether distinctions based on surface
membrane phenotype or Ig V gene mutation status might predict different
clinical courses and outcomes.
Our data indicate that both the percentages of CD38+ B-CLL
cells and the presence or absence of Ig V gene mutations
(VH + VL) can be used as prognostic
indicators in this disease. Because the percentage of CD38+
B-CLL cells inversely correlates, in a statistically significant manner, with the presence or absence of Ig V gene mutations in B-CLL,
CD38 may be the preferred adjunct to the current staging systems
because of its relative ease of ascertainment.
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MATERIALS AND METHODS |
Patients.
The Institutional Review Boards of North Shore University Hospital,
Manhasset, NY, and Long Island Jewish Medical Center, New Hyde Park,
NY, approved these studies. The patients in this study are a subset (n = 47) of the well-defined cohort (n = 64) of randomly chosen, typical
IgM+ B-CLL patients described previously.21
Patients were selected for the present study based on the availability
of detailed clinical histories (Don Monti Division of Medical Oncology,
North Shore University Hospital, and the Hematology/Oncology Division,
Long Island Jewish Medical Center) and the availability of DNA
sequences for both the Ig VH21,24 and
VL (Ghiotto et al, in preparation) genes in
each case. The clinical courses of the patients that were analyzed in
this study were not significantly different from those that could not
be studied because of lack of sample or follow-up. There were 34 males
and 13 females in this group, with a mean age of 63.4 years (range, 38 to 80). The mean ages of the unmutated (mean, 61.3; range, 38 to 79)
and mutated (mean, 65.5; range, 47 to 80) cases or of the 30%
CD38+ (mean, 63.5; range, 38 to 79) and <30%
CD38+ (mean, 63.6; range, 44 to 79) cases were similar.
Fresh or cryopreserved B-CLL cells were available for surface marker
analyses on 37 patients (20 unmutated and 17 mutated). These samples
had been obtained at various points in the clinical follow-up of these
patients. There were no differences in the timing of sample acquisition
between the unmutated and mutated groups.
Cellular immunophenotypic analysis.
The following antibody conjugates were used: anti-CD23-fluorescein
isothiocyanate (FITC; Immunotech, Inc, Westbrook, ME), goat antihuman
IgD-FITC (Southern Biotechnology Associates, Birmingham, AL), and
anti-CD5-FITC, anti-CD5-phycoerythrin (PE), anti-CD38-PE, anti-CD19-allophycocyanin (APC), anti-CD45-FITC, and anti-CD14-PE (Simultest LeucoGATE; all from Becton Dickinson Immunocytometry Systems, San Jose, CA).
Peripheral blood mononuclear cells (PBMC) were separated from
heparinized venous blood by density gradient centrifugation using
Ficoll-Paque (Pharmacia LKB Biotechnology, Piscataway, NJ) and used
either immediately or after thawing samples that had been cryopreserved
with a programmable cell freezing machine (CryoMed, Mt. Clemens, MI).
PBMC were analyzed for surface expression of CD19/CD5/CD38 and
CD19/IgD/CD38 and CD19/CD5/CD23 by triple color immunofluorescence.25 For the detection of
CD19/CD5/CD38-expressing cells, monoclonal antibody (MoAb) labeled with
the following fluorochromes were used: anti-CD19-APC,
anti-CD5-FITC, and anti-CD38-PE; for the detection of
CD19/IgD/CD38-expressing cells, anti-CD19-APC, anti-IgD-FITC, and
anti-CD38-PE MoAb were used; for the detection of
CD19/CD5/CD23-expressing cells, anti-CD19-APC, anti-CD23-FITC, and
anti-CD5-PE MoAb were used. Isotype-matched negative controls were
used in all assays to determine positive from negative results. Flow
cytometric analyses were performed on a Becton-Dickinson FACS Calibur
flow cytometer equipped with argon and red diode lasers. Measurements
of forward and side scatter were combined with CD45 and CD14
determinations to identify lymphocytes and exclude monocytes. The
CellQuest software system (Becton Dickinson Immunocytometry Systems)
was used to acquire and analyze data.
Statistical analyses.
The percentages of CD5+/CD19+ B cells that
coexpressed CD38 or IgD or CD23 were determined for each patient and
statistical differences between the unmutated and mutated groups
analyzed using the Mann-Whitney test. Patients were also classified
according to the percentage of B-CLL cells expressing CD38 into 30%
CD38+ and <30% CD38+ groups.
To determine the degree of association between the individual patients
based on the actual percentages of CD38-expressing cells and on the V
gene mutation status or on the percentages of CD23-expressing cells,
the Spearman coefficient was calculated. To determine the degree of
association between the patients classified into 2 groups based on
percentages of CD38-expressing cells and on the V gene mutation status,
the Kappa coefficient was used. Standard methods for estimating
proportions and associated exact confidence intervals (CI) were used
for estimating sensitivity of high numbers of CD38+ B-CLL
cells (30%) as a marker for "unmutated" V genes. In standard epidemiological terminology, the unmutated gene corresponded to the
"disease" state and accordingly sensitivity was computed using the number of patients with unmutated genes as the denominator. Similarly, specificity of low numbers of CD38+ B-CLL cells
(<30%) was computed using the patients with mutated genes as the
denominator. Accuracy was defined as the percentage of patients who
were classified correctly as unmutated or mutated using the CD38
criteria. Positive and negative predictive values were computed using
Bayes' Rule.
Comparisons of V gene mutation status and CD38 expression with clinical
course were made "blindly". The investigator (T.W.) who reviewed
the clinical histories of these patients was unaware of the laboratory
data during the retrospective chart review. The two-tailed Fisher's
Exact test was used to determine whether chemotherapy requirements, Rai
stage at diagnosis, or gender were significantly associated with V gene
mutation status or with CD38 percentage. Survival analyses were
performed using the Kaplan-Meier product-limit method and the log-rank test.
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RESULTS |
Percentages of CD38+ B-CLL cells among the unmutated and
mutated cases.
The DNA sequences of the Ig VH and VL genes
expressed by the leukemic cells of the 47 typical IgM+
B-CLL cases included in this study were determined previously. Based on
the numbers of somatic mutations detected in these genes, the cases
were divided into 2 categories: "unmutated" or "mutated". As per current convention, "unmutated" cases were defined as
those with <2% differences from the most similar germline gene in
both the expressed VH and VL genes;
"mutated" cases were defined as those in which the B-CLL cells
displayed 2% differences in either the expressed VH or
VL gene.
To determine whether these genetic differences reflected cellular
phenotypic differences, we analyzed the expression of CD5, CD23, CD38,
and IgD on the B-CLL cells of the 37 patients in whom PBMC were
available (20 unmutated and 17 mutated). Analyses of CD38 and IgD
expression were chosen for these studies because they distinguish B
cells at various stages of differentiation.22,23
The unmutated and mutated B-CLL cases were similar in CD19+
B cells coexpressing CD5, CD23, and IgD, both in the percentages of
positive cells and in mean fluorescence intensity (data not shown).
However, the percentage of CD38+ cells was dramatically
different between the unmutated and mutated cases.
Figure 1 illustrates 8 representative B-CLL
cases analyzed for CD19/CD5/CD38-expressing cells. The VH
and VL genes of the 4 cases listed in the upper panel were
not mutated, whereas the VH and/or VL genes in
the lower panel were mutated. Note that the unmutated cases have a much
higher percentage of CD38+ cells among the
CD5+/CD19+ cells than the mutated cases in the
lower panel.
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| Fig 1.
Representative flow cytometric profiles of CD38
expression on mutated and unmutated
CD5+/CD19+ B-CLL cases. B-CLL cases were
analyzed by flow cytometry after exposure to anti-CD19-APC,
anti-CD5-FITC, and anti-CD38-PE. The events illustrated were obtained
by gating on cells expressing CD19. Density plots of CD38 and CD5
expression are shown for 8 representative B-CLL cases. The upper 4 cases had less than 2% mutations in either the VH or
VL genes, whereas the lower 4 cases had mutations in the
VH and/or VL genes.
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When the percentages of CD38+ B-CLL cells in the unmutated
and mutated groups were compared statistically, very significant differences were found (means, 63.9% v 7.3%, respectively;
P = .00001). The Spearman correlation between the individual
percentages of CD38+ B-CLL cells in each case versus the
actual percentages of V gene mutations was r = -0.75 (P < .001), indicating a relatively strong inverse relationship. A low to
moderate direct correlation existed between the percentages of
CD23+ B-CLL cells and the percentage of V gene mutation (r = 0.42; P = .01). There was no correlation between CD38
expression and CD23 expression (data not shown).
When the results on percentages of CD38-expressing cells were plotted
individually ( Fig 2), the cases could be segregated into 2 distinct sets, 1 with 30% CD38+ cells and the
other with <30% CD38+ cells. The 30% cut off value was
chosen empirically based on the observed distributions on the plot.
Furthermore, an inverse relationship existed between CD38 expression
and V gene mutation status. The set with the higher percentages of
CD38+ B-CLL cells was comprised solely of unmutated cases,
whereas the set with the lower percentages of CD38+ cells
contained all of the mutated cases and 3 of the unmutated cases. The
Kappa coefficient calculated for association between these 2 sets of
CD38+ B-CLL cases versus the unmutated and mutated groups
was -0.84, indicating a strong inverse relationship.
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| Fig 2.
Percentages of
CD38+/CD5+/CD19+ cells among
mutated and unmutated B-CLL cases. The percentages of CD38-expressing
B-CLL cells among patients (n = 37) whose Ig VH and
VL genes had been sequenced. Unmutated cases ( ) display
<2.0% differences from the most similar germline gene; mutated
samples ( ) display 2% differences. Note that all of the cases
(17 of 17) that have 30% CD38+ B-CLL cells were
unmutated, whereas only 3 unmutated cases expressed low numbers
(<30%) of CD38+ B-CLL cells. These comparisons are
statistically significant (P = .00001; Mann-Whitney test).
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Furthermore, high percentages of CD38+ B cells (30%)
indicated the presence of <2% mutations with 100% specificity (95%
CI: 84% to 100%). Because 3 patients with unmutated V genes were
found to have <30% CD38+ B-CLL cells (Fig 2), the
sensitivity of using 30% CD38+ B-CLL cells as a marker
for significant percentages of VH or VL gene
mutations was 85% (95% CI: 62% to 97%). Based on this specificity
and sensitivity and on a prevalence of 60% for 2% mutations in
either VH or VL, the positive predictive value
of 30% CD38+ B cells indicating the "unmutated"
genotype was 100%. Conversely, the predictive value of <30%
CD38+ B cells indicating the "mutated" genotype was
82%. These CD38 criteria indicate V gene mutation status with 92% accuracy.
The differences in CD38 expression were stable over time and were not
influenced by chemotherapy. Sixteen patients (7 with CD38 values 30%
and 9 with <30%) were studied at 2 or more time points, separated by
as much as 6 years. Indeed, the percentages of CD38+ B-CLL
cells detected never differed by more than 10% in any instance. One
patient with 95% circulating CD38+ B-CLL cells was studied
on 5 occasions over a 24-month period and the percentages of
CD38+ cells detected in each sample were very similar
(<5% difference).
Clinical course and outcome of the unmutated versus mutated B-CLL
cases.
The treatment histories of the patients with unmutated and mutated Ig V
region genes were very different (Table 1).
Eighteen of the 23 mutated cases (78.3%) required either no
chemotherapy (52.2%) or minimal treatment (26.1%), while only 20.8%
of the unmutated cases required no (16.6%) or minimal therapy (4.2%). These differences were highly significant (P = .0001).
Furthermore, 79.2% (19 of 24) of the unmutated cases required
continuous chemotherapy or chemotherapy using 2 or more agents or
regimens. Although 18 of these 19 patients (94.7%) received
fludarabine, only 2 achieved a durable clinical response.
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Table 1.
Comparison of Treatment Histories Based on Either Ig V
Gene Mutation Status or the Percentages of CD38+ B-CLL
Cells
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These significant differences in chemotherapy requirements were
reflected in significant differences in survival
(Fig 3A). The median survival of the
patients in the unmutated group was 9 years, whereas median survival
for the mutated group was not reached for the duration of follow-up
(P = .0001).
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| Fig 3.
Survival based on V gene mutation status and CD38
expression. (A) Kaplan-Meier plot comparing survival based on the
absence ("unmutated": . . . . . . ) or presence
("mutated": ____) of significant numbers (2%) of
V gene mutations in 47 B-CLL cases (unmutated: 24 cases; mutated: 23).
Median survival of unmutated group: 9 years; median survival of mutated
group not reached; P = .0001; log-rank test). (B)
Kaplan-Meier plot comparing survival based on the detection of 30%
(. . . . . . ) or <30% CD38+ B-CLL cells
( 30%: 17 cases; <30%: 19). Median survival of the 30%
CD38+ group: 10 years; median survival of the <30%
CD38+ group: not reached (P = .0001; log-rank
test).
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Finally, we compared V gene mutation status with the clinical stage at
the time of diagnosis using the modified Rai system. Our patients
stratified to all Rai modified clinical stages at the time of diagnosis
(Table 2). Patients who stratify to the Rai
intermediate risk group are the most heterogeneous in treatment requirements and survival and represent those in whom outcome is the
most difficult to predict.1,7 Therefore, we analyzed the
survival of the 25 patients in this group (9 mutated cases v 16 unmutated cases; Fig 4A). The median
survival of the unmutated cases was 9 years, compared with 17 years for
the mutated cases (P = .0007).
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Table 2.
Comparison of Modified Rai Stage at Diagnosis With Ig V
Gene Mutation Status and the Percentages of CD38+ B-CLL
Cells
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| Fig 4.
Survival based on V gene mutation status and CD38
expression among B-CLL patients who stratify to the Rai intermediate
risk category. (A) Kaplan-Meier plot comparing V gene mutation status
with survival among the cases within the Rai intermediate risk category
(unmutated: 16 cases; mutated: 9). Median survival of the mutated
group: 9 years; median survival of the unmutated group: 17 years
(P = .0007; log-rank test). (B) Kaplan-Meier plot comparing
numbers of CD38+ B-CLL cells with survival among the
cases within the Rai intermediate risk category (30%: 11 cases;
<30%: 9). Median survival of the 30% CD38+ group: 10 years; median survival of the <30% CD38+ group: not
reached (P = .0030; log-rank test). None of the patients in
the <30% CD38+ group died during the follow-up
period.
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Clinical course and outcome of B-CLL cases with 30% or <30%
CD38+ cells.
Because there was a significant correlation between V gene mutation and
CD38 expression by the B-CLL cells, we also compared chemotherapy
requirements and survival as a function of the percentages of
CD38+ leukemic cells. Significant differences were found
for both. Seventy-three percent (14 of 19) of the <30%
CD38+ cases required either no or minimal chemotherapy,
compared with 23.5% (4 of 17) of the 30% CD38+ cases
(P = .0067; Table 1). Conversely, 76.5% of the 30%
CD38+ cases required either continuous chemotherapy or
chemotherapy with 2 or more agents or regimens.
Median survival for the patients in the 30% CD38+ group
was 10 years (Fig 3B). In contrast, this value could not be determined for the patients in the <30% CD38+ group, as all
patients in this group were alive for the duration of follow-up
(P = .0001). Highly significant differences in
survival also were found among the patients in the Rai intermediate
risk group (Fig 4B). Median survival for the 30% CD38+
patients was reached in 10 years, whereas all patients in the <30%
CD38+ group remained alive throughout the years of
follow-up (P = .003).
Studies of IgG+ and IgA+ B-CLL cases.
The preceding observations were also true for a cohort of non-IgM
producing (IgG or IgA) B-CLL patients (n = 16), whose V gene sequence
analyses were published previously.21,24 The median
survival of the unmutated non-IgM cases was only 3 years, whereas it
was not reached for the mutated cases at 15 years (P = .004, log-rank test; data not shown). Similar data were obtained when the
cases were compared based on CD38 expression, although the small
numbers of available samples (n = 8) precluded accurate statistical analysis. When these non-IgM+ cases were pooled
with the IgM+ cases described above (bringing the total
number of patients studied to 63), the median survival for the
unmutated group (n = 29) was 8 years and for the mutated group (n = 34)
was not reached for the duration of follow-up (P = .0001). Similar data were obtained for the CD38 groups: median survival
for the 30% CD38+ (n = 19) was 9 years,
whereas median survival for the <30% CD38+ group
(n = 25) was not reached (P = .0001).
Gender of the B-CLL cases based on either V gene mutation or CD38
expression.
The cohort of IgM+ B-CLL patients in this study consisted
of 34 males and 13 females (M:F = 2.6:1). However, the M:F ratio of the
patients stratified by either V gene mutation status or CD38 expression
was very different (Table 3). In the
mutated group, males and females were virtually equally distributed,
whereas in the unmutated group, a marked male predominance was found
(M:F = 11:1; P = .003). A similar disparity in gender
distribution was seen when the patients were compared based on the
percentages of CD38+ B-CLL cells. The numbers of males and
females among the <30% CD38+ group were almost equal
(M:F = 1.1:1), whereas males outnumbered females in the 30%
CD38+ group (M:F = 7.5:1; P = .031).
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DISCUSSION |
The preceding data indicate that Ig V gene mutation status and CD38
expression are distinct and reliable prognostic indicators of clinical
course and outcome in B-CLL. Indeed, those patients in either the
unmutated or 30% CD38+ groups experienced a worse
clinical course than those patients in the mutated or <30%
CD38+ groups. This was true for both chemotherapy
requirements (Table 1) and survival (Fig 3).
Possibly our most clinically relevant correlation was found among those
patients who presented initially in the Rai intermediate risk category
(Fig 4). These patients are frustratingly difficult for clinicians to
treat because they can have either an indolent course requiring no or
minimal therapy or a rapid downhill course despite aggressive
treatment. Both CD38 expression and V gene mutation status were able to
segregate those Rai intermediate risk patients who followed an indolent
course from those whose course was much more aggressive (Fig 4).
Relevant to our observations on Ig V gene mutations and survival is the
study of Oscier et al26 indicating that B-CLL cells with
unmutated VH genes frequently contain 3 copies of
chromosome 12, a cytogenetic marker that is associated with poor
clinical outcome. This study was recently extended by Hamblin et
al26a to a larger cohort of patients. These new data are
consistent with our observations and show clearly that unmutated
VH genes are associated with a more aggressive form of
B-CLL.
When our patients were stratified according to V gene mutation status
or CD38 expression (Table 3), a clear preponderance of males was noted
in the unmutated and 30% CD38+ (poor outcome) groups
(M:F: 11:1 and 7.5:1, respectively). These ratios are much higher than
those reported previously.5 Our data, however, agree with
the studies indicating that women with B-CLL have a more favorable
clinical course than men. Although women comprised only ~10% of the
unmutated and 30% CD38+ (poor outcome) groups, they
constituted ~50% of the mutated and <30% CD38+ (good
outcome) groups (Table 3). These data support a role for gender
indirectly influencing clinical outcome and possibly B-cell maturation
and differentiation. The mechanism(s) responsible for these differences
are obscure at this point.
The 2 sets of B-CLL cases characterized in this study appear to
represent B cells transformed at different stages of B-cell differentiation and/or activation. Thus, those B-CLL cases with mutated
V genes and low numbers of CD38+ B-CLL cells are
characteristic of post-GC, memory B cells.22,23 Some of
these B-CLL cells may be derived from the small subset of
IgM+/IgD+ memory cells found in the
blood27 or bone marrow28 or from cells similar
to the IgD+ memory B cells identified in
tonsils.29 Although CD27 is another marker that
distinguishes pre-GC from post-GC B cells,27,30,31 we did
not find differences in CD27 expression among our CD5+
B-CLL cases, either in density per cell or in cell number (data not
shown). These data are in agreement with those of
others.32,33
In contrast, those B-CLL cases with unmutated V genes and high numbers
of CD38+ B-CLL cells display surface markers characteristic
of B cells that have not entered a GC. Because CD38, as detected by
MoAb conjugated with PE, is expressed on most blood B
cells,34 the 30% CD38+/unmutated B-CLL cells
could be derived from either naïve B cells or activated B cells
that have not entered a GC and have not generated Ig V gene mutations.
Based on analyses of the HCDR3 characteristics of unmutated B-CLL
cases,21,35 we favor the hypothesis that some of these
unmutated B-CLL cells have been activated and selected by foreign or autoantigen.
The physiological significance of CD38 expression primarily by the
unmutated cases and its potential function in cell survival and
proliferation is presently unknown. However, previous studies suggest
that CD38 expression identifies those B-CLL clones that are capable of
transducing signals through their B-cell antigen receptors that may
increase or decrease their chance for survival.36,37 In
this regard, Zupo et al38 have reported that
CD38+ B-CLL cells can be induced to undergo apoptosis in
vitro after exposure to anti-Ig antibodies, whereas
CD38 B-CLL cells are resistant to these effects.
Although these data appear to be at variance with our clinical
observations that those B-CLL cases with higher percentages of
CD38+ B cells have a worse clinical outcome, the quality of
the antigen receptor stimulus and the presence of associated stimuli
may lead to diverse endpoints (apoptosis v survival).
Similarly, triggering through the CD38 molecule can have different
effects on the survival of B cells depending on the state of
maturation/activation of the cell. Whereas anti-CD38-mediated
signaling results in the death of immature B cells,34
mature B cells can be rescued from apoptosis by CD38
triggering.36,37 Further studies will be necessary to
determine how these in vitro data correlate with our clinical observations.
In conclusion, our studies identify CD38 expression and V gene mutation
status as novel prognostic indicators that appear to identify mutually
overlapping groups of B-CLL patients (Figs 1 and 2 and Results).
However, because CD38 expression can be determined more conveniently
and rapidly than Ig V gene mutations, this parameter may be the
preferred adjunct to the current staging systems. Indeed, the results
of this simple test should enable physicians to predict with
considerable accuracy whether a patient is likely to have a favorable
or unfavorable clinical course. Furthermore, because the leukemic cells
appear to be fixed in their level of expression of this marker,
determining the percentage of CD38+ B-CLL cells may be
useful at any point in the clinical course of the individual B-CLL
patient. However, we cannot exclude the possibility that CD38
expression might change with the alterations in chromosomal structure
and gene expression that occur in Richter's transformation.39-41
It will be important to confirm our findings and to compare more
extensively the value of CD38 expression versus V gene mutation status
as prognostic indicators. In addition, these 2 indicators need to be
compared and correlated with other prognostic markers such as
lymphocyte doubling time,11 circulating levels of
2microglobulin12,13 and soluble
CD23,14 serum thymidine kinase levels,15,16
bone marrow histology,17 and cytogenetic
abnormalities.18
| |
ACKNOWLEDGMENT |
We thank Cathy Rapelje and Grace Lee for performing flow cytometric
analyses, Drs Qiuhu Shi, Cristina Sison, and Martin L. Lesser for
performing statistical calculations, Gurmeet Sahansra for helping with
chart review, and Drs Charles C. Chu, Thomas J. Degnan, and Peter K. Gregersen for critically reviewing the manuscript.
| |
FOOTNOTES |
Submitted March 11, 1999; accepted May 6, 1999.
R.N.D. and T.W. contributed equally to this study.
Supported in part by US Public Health Service (USPHS) Grant No. AI
10811 from the National Institutes of Health (NIH) National Institute
of Allergy and Infectious Diseases (NIAID), the Joseph Eletto Leukemia
Research Fund, the Jean Walton Fund for Lymphoma and Myeloma Research,
the Sass Foundation for Medical Research, and the Richard and Nancy
Leeds Fund of the Department of Medicine of North Shore University Hospital.
The publication costs of this
article were defrayed in part by
page charge payment. This article
must therefore be hereby marked
"advertisement"
in accordance with 18 U.S.C. section
1734 solely to indicate this fact.
Presented in part at the 40th Annual Meeting of The
American Society of Hematology, held in Miami Beach, FL, December 4-8, 1998.
Address reprint requests to Nicholas Chiorazzi, MD, North Shore
University Hospital, 350 Community Dr, Manhasset, NY 11030; e-mail:
nchizzi{at}nshs.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
