Innumerable biological investigations require comparing different members of a collection of entities with respect to one or more properties. The conclusions to be drawn from such studies are based on an analysis of the degree of similarity or dissimilarity among the different members. For example, one might compare the activity of different isoforms or fragments of a protein of interest, or compare wild type protein(s) with various mutant versions of a protein that causes a disease state. Many additional examples come from comparisons of data sets derived from microarray and proteomics studies, as well as population genetics. Given the technical advances of recombinant DNA technology and the explosion in genomics over the past few years, it is a certainty that the number of these sorts of comparative studies, and the number of entities to be compared within each study, will increase dramatically in the near future. Unfortunately, the vast majority of such comparative studies are currently performed manually, with investigators searching for similarities and dissimilarities among different test entities "by eye". This is especially difficult when each member of the collection is being characterized by multiple criteria. The analytical process is time consuming, likely to miss subtleties and is susceptible to inadvertent bias and human errors. Development and application of computer-assisted modeling and visualization can provide extraordinarily valuable data analyses and interpretive tools for assessing relationships among different members in a study.

Microtubules represent one of the three main components of the eukaryotic cellular cytoskeleton 1. They are hollow, unbranched cylinders, formed by the non-covalent association of αβ tubulin dimer subunits. Microtubules serve a wide variety of essential structural and transport functions, including the segregation of chromosomes during cell division and the transport of vesicular cargo up and down long axonal processes in neurons.

Microtubules are highly dynamic structures, gaining and losing tubulin dimer subunits by a stochastic process known as dynamic instability 23. A large body of data, both pharmacological and somatic cell genetics, has led to the conclusion that proper regulation of microtubule dynamics is essential in order for microtubules to perform their many critical cellular functions (for review, see 4). For example, the effectiveness of the anti-cancer drug taxol derives from its ability to suppress microtubule dynamics, thereby interfering with the ability of cancer cells to proliferate 5. Given the importance of properly regulated microtubule dynamics, it is not surprising that cells have evolved a host of regulatory proteins that finely tune microtubule dynamics, including tau, MAP2, MAP4, SCG10 and stathmin.

The microtubule associated protein tau is essential for the normal development and maintenance of the nervous system 678. It binds directly to microtubules 910, and its ability to regulate microtubule dynamics 111213 is itself tightly regulated by both alternative RNA splicing 14 and phosphorylation (for review, see 15). Alternative RNA splicing leads to the synthesis of two classes of tau, known as 3-repeat tau and 4-repeat tau (See Figure 1 for a schematic). Whereas normal human fetal brain expresses only 3-repeat tau, adult human brain expresses approximately equal amounts of 3-repeat and 4-repeat tau. Despite this dramatic developmental shift in expression profiles, the functional and mechanistic differences between 3-repeat and 4-repeat tau remain poorly understood. While it is well-established that 4-repeat tau is a more potent regulator of microtubule dynamics than 3-repeat tau, there have been indications over the years that the two classes of tau isoforms may also have inherent qualitative differences as well 1216171819.

Abnormal tau action has long been correlated with neurodegeneration. Indeed, the classic neurofibrillary tangle pathology of Alzheimers and many related dementias are composed primarily of aberrant tau (for example, see 20). In 1998, a direct cause and effect relationship between errors in tau action and/or regulation and neurodegeneration was established by the genetic linkage between mutations in the tau gene and FTDP-17, a fronto-temporal dementia with many similarities to Alzheimers disease 212223. Two classes of tau mutations have been described. The first collection of mutations are structural in nature, caused by various amino acid substitutions in tau. The second class of mutations are especially subtle and provocative – they are caused by errors in alternative tau RNA splicing that alter the expression ratio of otherwise normal 4-repeat and 3-repeat tau molecules. Specifically, rather than a ~50/50 ratio in adult human brain, the mutant ratio is closer to ~75/25. In both the structural and regulatory mutations, the result is early onset of neuronal cell death and dementia.

Unfortunately, the molecular mechanisms underlying tau-mediated neuronal cell death remain unclear. One widely held model suggests that errors in tau action lead to the aggregation of tau into neurofibrillary tangles, which are in turn cytotoxic 24. An alternative model suggests that tau-mediated neuronal cell death results from the inability of tau to properly maintain microtubule dynamics within a narrow range of activities required for cell viability 4131925. Additional models have also been proposed (see http://www.alzforum.org/res/adh/cur/default.asp).

To quantitatively investigate the regulation of microtubule dynamics under varying conditions (for example, with different tau isoforms or tau:tubulin molar ratios), cell biologists employ video microscopy to visualize and record images of dynamic microtubules in real time. For each condition being assessed, many different individual microtubules must be imaged, tracked and analyzed 19. From the resulting microtubule "life history plots" (Figure 2), the dynamic behaviors of similarly treated microtubules can be determined, such as average growth or shortening rates. Subsequently, the behavior of microtubules under different conditions can be compared.

Computer-assisted methods are especially attractive for time series investigations of this sort. In the specific case of analyzing the regulation of microtubule dynamics, inadvertent bias and non-reproducibility in data interpretation among different labs and different investigators when defining the beginning and end points of individual growth, shortening or attenuation events could become significant. Despite the fact that these events are explicitly defined, investigators must make many judgment calls. In contrast, computer-assisted methods offer a faster and more objective assessment of the data. More importantly, these methods can also provide analytical tools as much as determine the fit of the data to various statistical models, thereby testing various conceptual representations of the underlying molecular mechanisms of action of the system under study. Modeling can also generate testable mechanistic predictions for subsequent investigations. In a general sense, sophisticated computational tools have the potential to make major contributions to many areas of biological research.

We first developed an automated method to identify the different events – growth, shortening, and attenuation ("pause") – on microtubule life-history plots, using a set of pre-defined rules (see the Methods section for details). We then compared the ability of this automated method to determine average microtubule growth rates with standard manual analysis, using data sets assessing the ability of tau to regulate microtubule dynamics from 19. In this earlier work, microtubule dynamics were assayed under nine different experimental conditions. As seen in Table 1, the deviation between automatic and manually determined rates ranges from 3.33% to 12.68%, with an average deviation of 6.59%. Statistically, the differences between the manually determined values and the automatically measured values are not significant (as shown by the p-values), except for one condition. The p-value is computed by performing a t-test of the manually determined growth rates against the automatically computed ones for each condition (details are in the Methods section). More importantly, the relative order of the conditions do not change, and the degrees of separation are well maintained. Table 2 shows the comparison for the same set of conditions using a different tubulin preparation from 19. Again, our automated method accurately recapitulates manual analysis with increased objectivity. Additionally, it markedly reduces the time required to conduct these investigations.

It is also important to note that inherent biological variability exists in the microtubule growth rate data. This likely results from biochemical variations between different tubulin preparations, such as different tubulin isoform expression ratios and/or varying degrees of post-translational modifications, such as phosphorylation, acetylation or tyrosination. For example, assuming each growth rate determination is within a variation of ± 0.1 μm/min, the rank order of the conditions for each of the two data sets is quite similar, although the 4R-1:55 and 3R-1:38 conditions are reversed (see Table 3). This inherent biological variability could limit the utility of some sophisticated and highly sensitive statistical models to make testable predictions regarding mechanisms underlying the regulation of microtubule dynamics. At the minimum, multiple data sets might be necessary and all predictions would need to be considered tentative until tested directly by other biological means.

Next, we sought to develop mathematical and statistical models to capture different dynamic aspects of microtubule behavior and to embed them in a two-dimensional space for visualization and easy comparison of different conditions. We used the Sammon projection method 27 for embedding and visualization. In short, the embedding process displays each experimental condition with an (x, y) position; the relative distance between the (x, y) positions of any pair of experimental conditions corresponds to their relative degree of relatedness (details are in the Methods section). The conditions of interest can be compared based on numerous parameters and the computational method is applicable to all kinds of numerical parameters.

The outline of our method is as follows. First, the experimental measurements are analyzed based on an appropriate mathematical model. Then, an appropriate dissimilarity function is applied to calculate the relative distances between the models of each pair of conditions. Finally, the conditions are embedded on a two-dimensional space such that the inherent structure of the data is approximately preserved. This is achieved by assigning points (x and y coordinates) to the models such that the Euclidean distance between any pair of points in this space is as close to the original dissimilarity measure between their models as possible. Unlike principal component analysis (PCA) 28, this method works with any distance matrix. The quality of the embedding is measured by distortion. For ideal embeddings, where all dissimilarity values are maintained exactly as Euclidean distances in the embedded space, the distortion is 1. The details of the models, the dissimilarity functions, the embedding algorithm, and the distortion computations are presented in the Methods section.

The different models described in this section capture different characteristics of microtubule dynamicity. Comparison of conditions across these models highlights different features of tau action.

In order to compare a pair of models, an appropriate similarity or dissimilarity function is necessary. The dissimilarity or distance measure is used to compute the distance matrix among the conditions; this distance matrix is then embedded in a two-dimensional vector space as described later in the Visualization section.

The distances among the experimental conditions, calculated by using the above methods, were visualized by plotting the conditions onto a two-dimensional vector space. This allows for easy comparison of the conditions and immediate comprehension of the structure of the data. The aim of the embedding method is to assign coordinates such that the Euclidean distance between any pair of conditions in the embedded space is as close as possible to the dissimilarity calculated between their models. The method can embed a given set of points into any dimensional space; here, we have chosen two for easy visualization purposes.

Formally, suppose there are two models, α and β, and the dissimilarity between them is d(α, β) according to some dissimilarity function d. If the embeddings of these two models in the two-dimensional vector space (x, y space) is given by e(α) = (x_α, y_α) and e(β) = (x_β, y_β), then the aim of the embedding function is to choose the coordinates e(α) and e(β) such that the relative difference between L₂(e(α), e(β)) and d(α, β) is minimum. When there are n such models, the embedding function should be chosen such that the relative cumulative difference for all the n(n - 1)/2 pairs is minimized.

Principal component analysis (PCA) 28 can also be used to project data onto a two-dimensional space. PCA chooses the axes along which the original data shows the highest variance. It does not take into account the distances among the points. More importantly, PCA cannot work with any general distance matrix and is used mostly as a dimensionality reduction technique.

We used the Sammon projection method 27 as the embedding procedure. This method has been successfully used to embed proteins on a two-dimensional space for clustering purposes 41. The method starts with a random point (random x, y coordinates) for each model. In each iteration, the points are updated according to a steepest descent algorithm such that the following error function E(x, y), which measures the relative differences between the original distances and the embedded distances, is decreased.

E ( x , y ) = 1 c ∑ ∀ α , β , α ≠ β [ ( d ( α , β ) − L 2 ( e ( α ) , e ( β ) ) ) 2 d ( α , β ) ] MathType@MTEF@5@5@+=feaagaart1ev2aaatCvAUfKttLearuWrP9MDH5MBPbIqV92AaeXatLxBI9gBaebbnrfifHhDYfgasaacPC6xNi=xI8qiVKYPFjYdHaVhbbf9v8qqaqFr0xc9vqFj0dXdbba91qpepeI8k8fiI+fsY=rqGqVepae9pg0db9vqaiVgFr0xfr=xfr=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@661D@

where

c = ∑ ∀ α , β d ( α , β ) MathType@MTEF@5@5@+=feaagaart1ev2aaatCvAUfKttLearuWrP9MDH5MBPbIqV92AaeXatLxBI9gBaebbnrfifHhDYfgasaacPC6xNi=xI8qiVKYPFjYdHaVhbbf9v8qqaqFr0xc9vqFj0dXdbba91qpepeI8k8fiI+fsY=rqGqVepae9pg0db9vqaiVgFr0xfr=xfr=xc9adbaqaaeGaciGaaiaabeqaaeqabiWaaaGcbaGaem4yamMaeyypa0ZaaabuaeaacqWGKbazcqGGOaakcqaHXoqycqGGSaalcqaHYoGycqGGPaqkaSqaaiabgcGiIiabeg7aHjabcYcaSiabek7aIbqab0GaeyyeIuoaaaa@3CAE@

In each iteration, a correction step is added to every dimension of every point. The direction of the correction is towards the gradient of the error. The coordinates of the point α in iteration i + 1 are updated as follows:

x α ( i + 1 ) = x α ( i ) − f × ∂ E ( i ) / ∂ x | ∂ 2 E ( i ) / ∂ x 2 | y α ( i + 1 ) = y α ( i ) − f × ∂ E ( i ) / ∂ y | ∂ 2 E ( i ) / ∂ y 2 | MathType@MTEF@5@5@+=feaagaart1ev2aaatCvAUfKttLearuWrP9MDH5MBPbIqV92AaeXatLxBI9gBaebbnrfifHhDYfgasaacPC6xNi=xI8qiVKYPFjYdHaVhbbf9v8qqaqFr0xc9vqFj0dXdbba91qpepeI8k8fiI+fsY=rqGqVepae9pg0db9vqaiVgFr0xfr=xfr=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@859A@

where E⁽ⁱ⁾ is the error after iteration i and f is a factor to control the step sizes. We used f = 0.2. The method stops after a certain number of steps or when there is no significant improvement in the error. We stopped the iterations either when the change in error went below 0.01% or up to a maximum of 1000 steps. The number of steps was set as an additional check in order to come out of any local error problems, e.g., oscillating error values. In practice, after 250–300 iterations, the error stopped changing, and the algorithms stopped. In addition, in order to counter the problem of bad initialization, the algorithms were run 5 times for each embedding and the one with the lowest error was picked. The final coordinates or the directions of the axes do not have any significance; only the Euclidean distances among the embedded points matter.

For any dimensionality reduction or embedding technique, an important measure of quality is distortion. Distortion measures the largest amount of discrepancy from an original distance value to the corresponding embedded distance. It is measured as

d i s t o r t i o n = max ⁡ { o r i g i n a l   d i s t e m b e d d e d   d i s t } min ⁡ { o r i g i n a l   d i s t e m b e d d e d   d i s t } MathType@MTEF@5@5@+=feaagaart1ev2aaatCvAUfKttLearuWrP9MDH5MBPbIqV92AaeXatLxBI9gBaebbnrfifHhDYfgasaacPC6xNi=xI8qiVKYPFjYdHaVhbbf9v8qqaqFr0xc9vqFj0dXdbba91qpepeI8k8fiI+fsY=rqGqVepae9pg0db9vqaiVgFr0xfr=xfr=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@8CF1@

where original dist refers to an original dissimilarity measure between two models and embedded dist refers to the Euclidean distance between the corresponding embedded points. For ideal embeddings, where all the original distances have been maintained exactly, the distortion is 1. For others, the distortion is greater than 1. In general, lower the distortion value, better the embedding. The individual distortions are measured by the ratio of embedded dist to original dist.

For models with only a single parameter, any dissimilarity between a pair of them is equal to the difference between their single parameters. Such distance matrices can be always embedded into two dimensions with distortion equal to 1. The models have to be simply embedded as points on a straight line with the order and the distances maintained, e.g., as (parameter, 0) or (parameter/2 MathType@MTEF@5@5@+=feaagaart1ev2aaatCvAUfKttLearuWrP9MDH5MBPbIqV92AaeXatLxBI9gBaebbnrfifHhDYfgasaacPC6xNi=xH8viVGI8Gi=hEeeu0xXdbba9frFj0xb9qqpG0dXdb9aspeI8k8fiI+fsY=rqGqVepae9pg0db9vqaiVgFr0xfr=xfr=xc9adbaqaaeGaciGaaiaabeqaaeqabiWaaaGcbaWaaOaaaeaacqaIYaGmaSqabaaaaa@2CE2@, parameter/2 MathType@MTEF@5@5@+=feaagaart1ev2aaatCvAUfKttLearuWrP9MDH5MBPbIqV92AaeXatLxBI9gBaebbnrfifHhDYfgasaacPC6xNi=xH8viVGI8Gi=hEeeu0xXdbba9frFj0xb9qqpG0dXdb9aspeI8k8fiI+fsY=rqGqVepae9pg0db9vqaiVgFr0xfr=xfr=xc9adbaqaaeGaciGaaiaabeqaaeqabiWaaaGcbaWaaOaaaeaacqaIYaGmaSqabaaaaa@2CE2@) points. In our implementation, we have not forced this explicitly; the method itself converges to a straight line plot. For models with two parameters, if the dissimilarity function is Euclidean, then, it is again possible to devise an embedding with distortion 1. The original parameter values will form the coordinates in the embedded space. For higher number of parameters or with other dissimilarity functions, in general, it is not possible to design embeddings with distortion 1. The distortions of each of the graphs are mentioned in the captions. Additional file 3 reports the individual distortions for each of the distances for all the embeddings.