Success of tumorsphere isolation from WHO grade IV gliomas does not correlate with the weight of fresh tumor specimens: an immunohistochemical characterization of tumorsphere differentiation

A subpopulation of glioblastoma (GBM) tumor cells possesses the ability to undergo neural differentiation and induce tumorigenesis [1‐3]. When cultured under appropriate conditions in vitro, this population of tumor cells gives rise to gliomaspheres, referred to more generically as tumorspheres (TSs). TSs have been isolated from various malignant tumors, including breast [4], prostate [5], bone [6], colon [7], kidney [8] and lung [9], as well as brain [3, 10‐14]. It was previously reported that the rate of isolation of TSs increase as the World Health Organization (WHO) grades of glioma rise [3]. Moreover, it is not possible to isolate TSs from GBM specimens in all cases, with reported isolation rates estimated at 43.8 % [3]. Notably, the ability to isolate TSs is a significant prognostic factor for overall survival in patients with primary GBM [15].

It is known that the weight of fresh specimens varies from one surgical procedure to the next. This raises the question of whether the weight of a specimen is a determining factor in the ability to isolate TSs from it. In some isolation protocols, it is suggested that a specimen weight of 200–500 mg is needed for isolation of TSs [11]. However, there is no established experimental relationship between the weight of fresh specimens and the isolation of TSs.

In this study, we assessed the predictive value of fresh specimen weight in determining the ability to isolate TSs, testing the hypothesis that the greater the weight of the specimen, the more effective the isolation of TSs. Thirty-five fresh specimens of WHO grade IV gliomas were divided into two groups, based on the ability to isolate TSs from them, and the relationship between specimen weight and TSs isolation was studied. We also evaluated the optimal cut-off weight of specimens for the isolation of TSs.

It has been assumed that TSs arise from a subpopulation of cells responsible for the initiation, maintenance, and recurrence of tumors [2, 18]. It is also commonly thought that TS-generating cells comprise some proportion of the tumor, and that a higher proportion of these TS-generating cells would be associated with a more aggressive tumor [3, 15, 19]. A previous study reported a significant increase in TS isolation rate in gliomas with increased WHO grades [3]. This suggested the related hypothesis that a larger specimen mass would tend to favor an increased TS isolation rate. Our test of this hypothesis, however, revealed no significant difference in specimen weights between TS-positive and -negative groups. We also found that the two groups were not different with respect to clinical characteristics, molecular factors, or pathological features that might influence TS isolation.

Siedel et al. [12] reported that most tumor samples with a size up to 0.5 cm³ are suitable for GBM TSs isolation. Some authors recommend 200- to 500-mg specimens for isolation of GBM TSs [11], and there have been some suggestions about the weight or volume of specimens for isolation of TSs from other kinds of cancers [5, 9, 20]. Most other TS-related studies have provided no description of the weight or volume of fresh specimens for TS isolation [19, 21‐24]. Generally speaking, reports such as those referred to above have assumed that, all other things being equal, larger specimens are better than smaller specimens for TS isolation [5, 7, 9, 11, 12]. However, no studies have compared TS-negative and -positive groups to establish optimal weights or volumes for TS isolation.

It is difficult to isolate TSs, and the efficacy of the procedure is low (from 1 to 30 %) [23, 25, 26]. Most studies on malignant tumors of the brain and other organs have reported TS isolation efficiencies up to 40–60 % [2, 3, 9, 15, 27, 28], similar to the results of the results of our current study. However, some authors have described sequential modifications of isolation techniques that improved efficiency from 40 to 90 % in GBM patients [18]. In this latter case, improvements in TS isolation involved fixes to technical problems associated with each stage, such as early vulnerability of surgical specimens, mechanical disruption, and removal of red blood cells and necrotic material from fresh specimens. Although studies such as this highlight the contribution of technical problems to the isolation of TSs, the fact that the ability to isolate TSs is correlated with poorer clinical outcome in various types of cancers [3, 15, 29‐33] indicates that success of TS isolation is not solely determined by technical issues.

Previous report proposed that primary GBM TSs isolation is a prognostic indicator of clinical outcome [15]. In addition, some authors described that TSs isolation is supposed to be a poor prognostic factor in other malignant gliomas [34]. In the current study, we evaluated the prognostic role of TSs in WHO grade IV gliomas. TS isolation from WHO grade IV gliomas were not significantly related to overall survival (data not shown), and there were no significant differences in clinical characteristics, molecular factors, or pathological features between TS-positive and TS-negative groups (Table 1). However, these results could be related to the short follow-up period (10 month), suggesting that long-term follow-up of this cohort is needed to assess the prognostic role of TS isolation in patients with WHO grade IV gliomas.

There are some concerns that surgical procedures used to collect fresh specimens can affect TS isolation. Some authors have reported that surgical procedures can help TSs exit from quiescence, inducing the formation of more TSs for analysis consequently [19]. On the other hand, surgically resected tissue is vulnerable to rapid ischemic and degenerative alterations [7, 19]. Thus, optimal conditions, including rapid transfer of specimens following surgical resection, removal of red blood cells and necrotic material and an appropriate environment for growth are required for the isolation of TSs from fresh surgical specimens [5, 7, 9, 11, 12, 18, 19, 23, 35]. Our laboratory has an ongoing effort to develop optimal conditions for the isolation of TS [2, 3, 10, 17].

RNA sequencing or gene expression arrays could be helpful in validating new TS markers and targets. However, the genome analyses necessary to establish transcription factors that might influence to TS isolation have not been performed. In this context, it has been shown that functional inhibition of microRNA-138 (miR-138) in malignant glioma prevents TS formation in vitro and impedes tumorigenesis in vivo [36]. In our study, we sought to determine whether the ability to isolate TSs differed depending on the weight of the specimen. However, further studies regarding transcription factors necessary for TS isolation are needed.

In our study, the specimen weight was 500 mg for the isolation of TSs to maximize sensitivity and specificity. This result was a little similar to the value reported by other authors [11]. Ideally, specimens would be subdivided into various sizes and then cultured, or more than one specimen would be procured from a single patient. However, in actual practice, the operating room setting imposes limitations on specimen collection. We tried to collect specimens with a minimum of red blood cells and necrotic material, but this made it difficult to gather specimens of different sizes from each patient. Therefore, we emphasized the absence of significant differences between demographic and clinical characteristics of two groups, and used the ROC curve for statistical processing. An analysis of our data yielded an area under the ROC curve of 0.618, which demonstrated poor discriminatory ability for the isolation of TSs [37, 38]. However, 500 mg of fresh specimen proved to be optimal in our study, and our summary data showed no significant difference in weight between the TS-positive and TS-negative groups, clearly ruling out size/weight of sample as a determining factor in successful TS isolation. Our study suggests some methods for improving the efficiency of TS isolation in addition to stage-specific technical modifications. Future studies using a larger numbers of cases are warranted to further address the relationship between the amount of fresh specimen and TS isolation rate.

Our initial hypothesis that a larger amount of specimen would translate to a higher rate of TS isolation proved to be incorrect. Instead, we found no relationship between the weight of specimen and TS isolation rate. Moreover, our data suggested that 500 mg of fresh specimen was optimal for isolation of TS with maximal sensitivity and specificity. The results of this study could provide useful technical information for cellular immortalization of patients with WHO grade IV gliomas.