Introduction

Chronic myelomonocytic leukemia (CMML) is a rare, genotypically and phenotypically heterogenous hematologic malignancy of elderly people with an intrinsic risk of progression and transformation into secondary acute myeloid leukemia (AML). With regard to the presence of myeloproliferation, CMML was originally subdivided into myeloproliferative disorder (MP-CMML; white blood cell count [WBC] count ≥ 13 G/L) versus myelodysplastic syndrome (MD-CMML; WBC count < 13 G/L) by the FAB criteria [1, 2]. Since CMML is characterized by features of both MDS and MPN, the World Health Organization (WHO) classification of 2002 assigned CMML to the mixed category, MDS/MPN [3]. CMML is further subclassified by the WHO into three groups based on blast equivalents (blasts plus promonocytes) in peripheral blood (PB) and bone marrow (BM) as follows: CMML‑0 if PB < 2% and BM < 5% blast equivalents; CMML‑1 if PB 2–4% or BM 5–9% blast equivalents; and CMML‑2 if PB 5–19% or BM 10–19% blast equivalents, and/or Auer rods are present [4]. CMML patients may have a highly variable outcome, suggesting that several factors can determine the course of disease and the causes of death in these patients [5,6,7,8,9]. There are a number of established prognostic parameters that have been incorporated into several prognostic models [10,11,12,13,14,15,16,17,18,19,20,21].

The estimated glomerular filtration rate is the clinical standard for the assessment of kidney function [22, 23]. It is based on a simple blood test that measures creatinine levels. The clinical and/or pathophysiological significance of increased creatinine levels in CMML is poorly investigated. Using the database of the Austrian Biodatabase for Chronic Myelomonocytic Leukemia (ABCMML), we analyzed 166 CMML patients with available information on creatinine values [24]. This information from a real-life database could be useful in the management of these patients.

Patients and methods

Patients

Recently, we have shown that the ABCMML may be used as a representative and useful real-life data source for biomedical research [24]. In this database, we retrospectively collected epidemiologic, hematologic, biochemical, clinical, immunophenotypic, cytogenetic, molecular, and biologic data of patients with CMML from different centers. The diagnosis of CMML and leukemic transformation were according to the WHO criteria [2,3,4]. Clinical and laboratory routine parameters were obtained from patient records. A detailed central manual retrospective chart review was carried out to ensure data quality before analysis of data from institutions. CMML patients in transformation were not included in this study.

For 166 CMML patients collected between 01.01.1990 and 31.03.2019, information was available regarding creatinine values. This research was approved by the ethics committee of the City of Vienna on 10 June 2015 (ethic code: 15-059-VK).

Molecular studies

Genomic DNA was isolated from mononuclear cell (MNC) fractions of blood samples according to standard procedures. The mutational status of CMML-related protein coding genes was determined by targeted amplicon sequencing using the MiSeq platform (Illumina, San Diego, CA, USA). Details regarding gene panel, library preparation, and data processing have been reported previously [24]. Only variants with strong clinical significance according to the Standards and Guidelines for the Interpretation and Reporting of Sequence Variants in Cancer and VAF ≥ 5% were used for statistical analysis regarding a potential predictive value for various treatment options.

Statistical analysis

The log-rank test was used to determine whether individual parameters were associated with overall survival (OS). OS was defined as the time from sampling to death (uncensored) or last follow-up (censored). A multivariate Cox regression analysis of overall survival was used to describe the relation between the event incidence, as expressed by the hazard function, and a set of covariates. Dichotomous variables were compared between different groups with the use of the chi-square test. The Mann–Whitney U test was used to compare two unmatched groups when continuous variables were not normally distributed. Results were considered significant at p < 0.05. Statistical analyses were performed with SPSS v. 27 (IBM Corp., Armonk, NY, USA); the reported p-values were two sided. A creatinine value of > 1.1 mg/dl was considered to indicate impaired renal function.

Results

Characteristics of patients

The baseline characteristics of the 166 patients with CMML are shown in Table 1. In order to make comparisons with other published CMML cohorts possible, the percentages of patients regarding established prognostic parameters are given [17]. As seen in other CMML series, there was a male predominance among study patients and more than half of the patients were aged 70 years or older [17]. Moreover, the proportion of patients with leukocytosis ≥ 13 G/L, anemia < 10 g/dL, thrombocytopenia < 100 G/L, and the presence of blast cells in peripheral blood (PB) was also comparable to other cohorts [17].

Table 1 Characteristics of chronic myelomonocytic leukemia patients

Prevalence of impaired renal function

Increased creatinine values (> 1.1 mg/dL) were found in 71 of 166 (43%) and normal values in 95/166 (57%) patients. In 65/159 (41%) patients, blood urea nitrogen levels were elevated (> 20 mg/dL). In records of 40 patients, causes for renal impairment were documented, including chronic renal failure (n = 24), hyperuricemia (n = 11), urolithiasis (n = 5), kidney anomalies (n = 4), acute renal failure (n = 3), hydronephrosis (n = 3), glomerulopathy (n = 2), stenosis of renal artery (n = 1), urinary tract infection (n = 1), and polycystic renal disease (n = 1). Patients with increased creatinine values had, as compared to patients with normal kidney function, a higher proportion of individuals with age ≥ 70 years (53/71 [75%] vs. 56/95 [59%], p = 0.035) and a higher proportion of males (57/71 [80%] vs. 60/95 [63%], p = 0.017).

Impact of impaired renal function on survival

As shown in Fig. 1, the median survival of patients with increased creatinine values was significantly shorter than among patients without impairment of renal function (20 vs. 52 months, p < 0.001). Among established prognostic parameters including leukocytosis ≥ 13 G/L, anemia < 10 g/dL, thrombocytopenia < 100 G/L, excessive monocytosis > 10 G/L, and the presence of blast cells in peripheral blood (PB), all of them except anemia had a significant adverse impact on survival in univariate analysis in the study cohort (Table 2). The significant effect of renal impairment was retained in multivariate analysis in the presence of these parameters (Table 3).

Fig. 1
figure 1

Kaplan–Meier plots for overall survival in chronic myelomonocytic leukemia patients with and without creatinine values > 1.1 mg/dL

Table 2 Univariate analysis of single prognostic parameters in patients with chronic myelomonocytic leukemia
Table 3 Hazard ratios, confidence intervals, and p-values of Cox regression analyses for survival including impaired renal function, leukocytosis, thrombocytopenia, monocytosis, and circulating blasts

Laboratory and molecular features in the presence or absence of impaired renal function

Patients with increased creatinine values were older (median age 74 vs. 72 years, p = 0.005) and were more often male (80% vs. 63%, p = 0.017). As shown in Table 4, patients with increased creatinine values had higher WBC counts, higher monocyte counts, and higher LDH values. As shown in Table 5, there was a trend toward a higher proportion of CBL and ASXL1 aberrations in patients with reduced renal function (CBL, 17% vs. 6%, p = 0.061; ASXL1, 40% vs. 24%, p = 0.051). Combining the most common mutations in cell signaling genes such as NRAS, CBL, and JAK2, the prevalence of these aberrations was 55% in CMML patients with renal failure as compared to 38% among patients with normal kidney function (p = 0.056).

Table 4 Phenotypic features including leukocytosis, anemia, thrombocytopenia, monocytosis, and circulating blasts stratified by the presence or absence of reduced renal function
Table 5 Genotypic features stratified by the presence or absence of impaired renal function

Discussion

Estimated glomerular filtration rate (eGFR) is the clinical standard for assessment of kidney function. It is based on a simple blood test that measures creatinine levels. The eGFR has been shown to have prognostic impact in patients and thresholds are therefore used for the definition and staging of chronic kidney disease [22, 23].

CMML is a rare, clinically, phenotypically, and genotypically heterogenous hematologic malignancy of elderly people with an intrinsic risk of progression and transformation into secondary AML. Depending on age, the risk of developing AML at 4 years is 13 to 39%, with a lower risk in higher age categories [9]. Thus, due to the advanced age of many CMML patients, a significant subgroup will not die from leukemia-associated death but rather from comorbidities. In order to offer individualized management, it is critical to know the prognostic impact of comorbidities in these patients. In this study, we determined the impact of chronic kidney disease on the outcome of CMML patients using creatinine levels, which were found in patient records of the ABCMML.

In this study, we were able to show that increased creatinine levels are associated with inferior survival. The significant effect of renal impairment was retained in multivariate analysis in the presence of established prognostic parameters in CMML, such as leukocytosis, anemia, thrombocytopenia, excessive monocytosis, and the presence of blast cells in PB. Although the proportion of older patients and males was higher among CMML patients with increased creatinine levels, these factors are not responsible for the shorter survival of CMML patients with impaired kidney function, since both parameters had no significant impact on survival in our study. The negative impact of reduced renal function in patients with CMML is, to the best of our knowledge, new in this patient group. The adverse prognostic impact of reduced renal function, however, has been demonstrated in other clonal myeloid disorders. In a retrospective study, Lucijanic et al. investigated a cohort of 176 myelofibrosis patients from five hematology centers [25]. CKD was present in 26.1% of MF patients and was significantly associated with older age, higher WBC counts, higher platelets, lower albumin, higher serum uric acid, higher LDH, and the presence of cardiovascular risk factors. The presence of chronic kidney disease (CKD) was associated with shorter overall survival and a shorter time to arterial and venous thrombosis. Moreover, in multivariate analysis, CKD was associated with shorter survival independently of the DIPSS. As reported by Christensen et al. in a longitudinal retrospective study including 143 patients with Philadelphia-negative chronic myeloproliferative neoplasms, 29% of patients had CKD stage 3 or 4 at the time of diagnosis [26]. Therein, 20% of patients had a rapid annual loss of eGFR and this parameter was negatively correlated to monocyte and neutrophil counts. In another retrospective analysis of 81 patients with AML reported by Pulko et al., CKD was present in almost half of the patients [27]. In this study, survival analysis again showed a statistically lower survival for CKD patients. Altogether, these findings show that impaired renal function has a negative impact on survival in patients with myeloid malignancies, including CMML.

The cause of impaired kidney function in our study remains unclear for most patients, but there are some indications in the literature which provide some possible explanations. In one study, 18 patients with myeloid neoplasms who were referred to a nephrology unit because of reduced renal function were retrospectively studied [28]. The study included 8 patients with CMML, 7 patients with essential thrombocytosis, 1 patient with polycythemia vera, and 2 patients with myelofibrosis. Patients developed kidney disease 7.7 years after diagnosis of the malignancy. Twelve patients had AKI at presentation. Eight patients had glomerular presentation (high-range proteinuria 33%, microscopic hematuria 56%). Kidney biopsy (n = 14) showed various patterns, including pauci-immune glomerulosclerosis (n = 5), extramedullary hematopoiesis (n = 6), or tubular atrophy and interstitial fibrosis with polymorphic inflammation (n = 8). In another histopathologic study of 29 patients with myeloid disorders including 4 patients with CMML, it was found that these patients showed significantly more chronic changes than age- and sex-matched controls, including global and segmental glomerulosclerosis [29], mesangial sclerosis, and hypercellularity, whereas the extent of arteriosclerosis was comparable. A third study characterized features of 11 patients with myeloproliferative neoplasm-related glomerulopathy that included 8 patients with primary myelofibrosis and 1 each with chronic myelogenous leukemia, polycythemia vera, and essential thrombocythemia [30]. Histologically, mesangial sclerosis and hypercellularity were seen in all 11 cases, segmental sclerosis in 8, features of chronic thrombotic microangiopathy in 9, and intracapillary hematopoietic cells in 4. On follow-up, 7 patients had persistent renal dysfunction and 4 progressed to end-stage renal disease. In single case reports, lysozyme-induced tubular injury has been described as a cause of kidney injury in patients with CMML [31]. We observed in our study an association of impaired kidney function with increased leukocyte counts, monocyte counts, and higher LDH levels. Molecular aberrations of NRAS, CBL, and JAK2, which are known to be related to patients with a MPN-like phenotype [32], were, although statistically different only in the case of CBL, numerically higher in CMML patients with reduced renal function. Altogether, these finding suggest that granulomonocytic proliferation is an important risk factor for the development of disturbance of kidney function.

There are several limitations that have to be considered in our study. First of all, creatinine levels, aside from chronic kidney disease, can be affected by other factors, including diet, muscle mass, malnutrition, and other chronic illnesses. Moreover, most of the information used in this study was derived from retrospective real-world data that were not collected systematically or prospectively. Thus, not every parameter was available in all patients. In addition, data from patient records were obtained over many years and from many different centers. Moreover, the patients included in this study were a relatively heterogenous population regarding the blast cell counts. However, real-world data have recently been recognized as an important way to get insights into the routine management and natural history of rare diseases [33]. CMML is a rare disease, and adequate patient numbers for a systematic and prospective study are not easy to collect within a limited timeframe. Moreover, the ABCMML provides information derived from molecular as well as from functional studies, and therefore allows a more comprehensive view and deeper insight into the complex pathophysiology of this hematologic malignancy [24].